Caryologia. International Journal of Cytology, Cytosystematics and Cytogenetics 75(3): 123-134, 2022 Firenze University Press www.fupress.com/caryologia ISSN 0008-7114 (print) | ISSN 2165-5391 (online) | DOI: 10.36253/caryologia-1728 Caryologia International Journal of Cytology, Cytosystematics and Cytogenetics Citation: Marlon Garcia Paitan, Maricielo Postillos-Flores, Luis Rojas Vasquez, Maria Siles Vallejos, Alberto López Sotomayor (2022). Nuclear DNA content and comparative FISH map- ping of the 5s and 45s rDNA in wild and cultivated populations of Physalis peruviana L. Caryologia 75(3): 123-134. doi: 10.36253/caryologia-1728 Received: July 03, 2022 Accepted: November 29, 2022 Published: April 5, 2023 Copyright: © 2022 Marlon Garcia Paitan, Maricielo Postillos-Flores, Luis Rojas Vasquez, Maria Siles Vallejos, Alber- to López Sotomayor. This is an open access, peer-reviewed article pub- lished by Firenze University Press (http://www.fupress.com/caryologia) and distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Data Availability Statement: All rel- evant data are within the paper and its Supporting Information files. Competing Interests: The Author(s) declare(s) no conflict of interest. Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in wild and cultivated populations of Physalis peruviana L. Marlon Garcia Paitan*, Maricielo Postillos-Flores, Luis Rojas Vasquez, Maria Siles Vallejos, Alberto López Sotomayor Research Group on Genetic Resources (RecGen), Faculty of Biological Sciences, Universi- dad Nacional Mayor de San Marcos, Lima, Peru *Corresponding author. E-mail: marlon.garcia@unmsm.edu.pe Abstract. Physalis peruviana L. often known as goldenberry, has increased its com- mercial growth in the international market in recent years due to its nutritional value and antioxidant potential. This situation has enabled countries such as Peru to increase their production in order to meet the global demand. However, investigations about the genetic diversity of cultivated and wild populations of goldenberry are still in their early stages. FISH mapping of 5s and 45s rDNA loci and flow cytometry estimation of nuclear DNA content were used to assess genetic differences between wild and culti- vated goldenberry populations from Ayacucho and Cajamarca. The majority of meta- phases had six 5s rDNA sites for all populations and two and four 45s rDNA sites for the cultivated and wild populations, respectively. We were able to characterize nine dif- ferent types of chromosomes based on their morphology, fluorescence, rDNA location, and conservation across populations by analyzing the chromosomes that contained rDNA. Furthermore, cultivated populations had more nuclear DNA (13.262±0.087 pg) than wild populations (12.955±0.086 pg). The results show genetic differences between wild and cultivated populations of goldenberry at molecular cytogenetic level as well as in genome size. These findings establish a precedent for future cytogenetic and genom- ic studies in goldenberry populations, enabling future breeding programs. Keywords: Goldenberry, FISH, rDNA, chromosomes, flow cytometry. 1. INTRODUCTION Physalis peruviana L., also known in Latin America as “aguaymanto,” “uchuva,” or “uvilla,” is a plant in the Solanaceae family that originated as well as diversified in the Andes Mountains. It produces orange-yellow berry- shaped fruits covered by a calyx. These fruits are high in vitamin C, carot- enoids, phenolic compounds with antioxidant precursors, and withanolides, which have anticancer and antitumor properties (Singh et al. 2019). Because of these characteristics and the increased international demand for organic food, the production of Physalis peruviana L. in Peru has quickly grown in recent years, establishing it as the second-largest producer of goldenberry 124 Marlon Garcia Paitan et al. in Latin America. However, the amount of goldenberry production compared to Colombia, the leading pro- ducer in Latin America, and other countries outside the American continent remains limited (Sierra y Selva Exportadora 2021). To increase commercial competitive- ness, genetic improvement programs that increase fruit quality and production must be implemented, and our understanding of the genetic diversity of Physalis peruvi- ana L. in cultivated and wild populations will determine the success of these programs. Cytogenetic studies pro- vide a foundation for the characterization of germplasm resources and offer guidance in selecting the parental cultivars for plant breeding programs (Herrera 2007). Furthermore, for future complex genomic projects such as cloning of genes of interest or genome sequencing, genome size data is essential to design effective projects (Doležel et al. 2007). Most cytogenetic studies in Physa- lis peruviana L. have used classical staining techniques to determine the chromosome number, where 2n=48 predominates (Rodríguez and Bueno 2006; Sánchez 2014; Liberato et al. 2014; Trevisani et al. 2018), while other studies report mixoploid plants (Sánchez 2014), and somatic aneuploidy (Carbajal et al. 2021). Karyo- typic formulas of some populations have been previously reported (Azeez and Faluyi 2019; Carbajal et al. 2021). However, since goldenberry chromosomes are small, numerous, and have similar morphology, the karyotype determination and its analysis are considered limited when classical staining techniques are used. FISH is a molecular cytogenetic technique for map- ping specific sequences on chromosomes by hybridizing probes with their complementary sequences. 5s and 45s ribosomal DNA (rDNA) probes have been widely used to perform cytogenetic characterization and to understand intraspecific and interspecific evolutionary relationships at chromosomal level by determining the position and number of signals on metaphase chromosomes, even in species with numerous and small chromosomes (Her- rera 2007). This is due to the nature of rDNA sequences, which are tandemly repeated DNA regions in the genome with high transcription rates and a predisposition for unequal recombination, which makes them inherent- ly unstable and prone to variation in copy number and location in the genome (Salim and Gerton 2019). Previ- ously, the number of 5s rDNA signals in two cultivated populations from the same region has been studied at the molecular cytogenetic level in Physalis peruviana L. (Siles et al. 2021). However, no studies have been conducted to analyze the number and position of the 5s and 45s rDNA sites to determine if there are any chromosomal differ- ences between wild and cultivated populations as a con- sequence of the domestication of the species. Plant genome size varies enormously and is consid- ered a biodiversity trait that provides valuable informa- tion for systematic and evolutionary studies (Pellicer et al. 2018). It is also useful for determining the genetic characterization of germplasm and plant identification because of these characteristics (Jedrzejczyk and Rewers 2020). Flow cytometry is a quick and easy way to esti- mate nuclear DNA content, making it a powerful tool for accelerating selection processes in plant breeding and providing critical data for sequencing projects (Ciprian- Salcedo et al. 2020). Given the foregoing, the goals of this study were to characterize and analyze the genetic differences between wild and cultivated populations of Physalis peruviana L. from the regions of Ayacucho and Cajamarca through the mapping of 5s and 45s rDNA by FISH, and to esti- mate the nuclear DNA content using flow cytometry. These two approaches will set a precedent as potential tools for programs to improve this genetic resource in Peru and, as a result, improve the international competi- tiveness of Peru against other producing countries. 2. METHODS AND MATERIALS 2.1 Plant material and preparation of metaphase chromo- somes Seeds were collected from wild and cultivated popu- lations of ripe goldenberry fruits in the Cajamarca and Ayacucho regions (Figure 1). Plant material was trans- ported to the Genetics Laboratory of the Universidad Nacional Mayor de San Marcos (UNMSM) and correctly identified as Physalis peruviana L. by the UNMSM Nat- ural History Museum. (Certificates 224-USM-2015 and 001-USM-NHN -2022). We modified the protocols described by Aguilera et al. (2016), Aliyeva-Schnorr et al. (2015), and Carbajal et al. (2021) in order to obtain mitotic metaphase chromo- somes. Goldenberry seeds were germinated, and roots with an approximate size of 4 mm were treated with 0.03 percent colchicine for 80 minutes at room temperature before being submerged in distilled water for 60 min- utes at 37 °C and fixed in an ethanol solution: acetic acid (3:1) at -20 °C for at least one day. Subsequently, the roots were washed in cold distilled water twice for 5 minutes, followed by two washes in cold citrate buffer (0.01 M at pH 4.6) for 5 minutes. They were then macerated in a 2% cellulase solution (from Aspergillus niger, Sigma) and a 10% liquid pectinase solution (from Aspergillus niger, Sigma) dissolved in 40% glycerol in 0.01M citrate buffer at pH 4.6, at 37 °C for 1 hour. Then, they were washed four times with cold citrate buffer for 5 minutes (0.01 M at pH 125Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in Physalis peruviana L. 4.6) and twice in ethanol 90° for 5 seconds. The apex of each root was then transferred to a slide, a drop of 45 per- cent acetic acid was placed on it, and the “squash” tech- nique was performed. After that, the slide was frozen with dry ice to remove the coverslip slide, then air-dried and examined under a phase-contrast microscope to confirm the presence of cells with properly separated metaphase chromosomes. Finally, the selected slides were immersed in absolute ethanol at -20 °C until they were used. 2.2 Amplification of rDNA Genomic DNA was extracted from seedlings grown from goldenberry seeds using the GF-1 Plant DNA extraction kit (Vivantis, Malaysia). To obtain the 5s rDNA probe, 5s rDNA amplification was performed using the primers pr5S14 (5’-GGCGAGTAGTACTAG- GATCCGTGAC-3’) and pr5S15 (5’-GCTTAACTTCG- GAGTTCTGATGGGA-3’) reported by Volkov et al. (2001). Because the 45s rDNA locus is too large to be completely amplified, it was decided to use the 18s rDNA gene as a probe. Since 18s rDNA is present within the gene structure of the 45s rDNA, mapping it would also show the location of the 45s rDNA locus. The following primers were used to achieve 18s rDNA amplification: primers F-566 (5’-CAGCAGCCGCGGTAATTCC-3’) and R-1200 (5’-CCCGTGTTGAGTCAAATTAAGC-3’) which were previously reported by Hadziavdic et al. (2014). The PCR reaction mixture for both cases had a final volume of 20 µl containing 1X PCR buffer, 1.5 mM MgCl2, 0.2 µM dNTPs, 0.2 µM of each primer, 1 U of Taq polymer- ase (abm, Canada), and 30 ng of genomic DNA. The PCR program for 5s rDNA began with an initial denaturation at 95 °C for 9 minutes, followed by 45 cycles of 95 °C for 30 seconds, 58 °C for 30 seconds and 72 °C for 45 sec- onds, and a final extension at 72 °C for 5 minutes. On the other hand, 18s rDNA involved an initial denaturation at 95 °C for 9 minutes, followed by 42 cycles of 95 °C for 30 seconds, 62 °C for 30 seconds and 72 °C for 60 seconds, and a final extension at 72 °C for 5 minutes. The ampli- cons were purified using the GeneJET PCR Purification kit (Thermo Scientific™) and quantified by spectropho- tometry. 2.3 Labelling of DNA probes The 5s rDNA amplicons were labeled with biotin- 14-dATP for 90 minutes using the BioNick Labeling System commercial kit (Invitrogen, USA), and the 18s rDNA was labeled for 180 minutes with digoxigenin- 11-dUTP using the DIG-Nick Translation Mix commer- cial kit (Roche, Switzerland). 2.4. FISH and signal detection The FISH methodology used was slightly modified from that provided by Poggio et al. (2000). The slides with the chromosome preparation were treated with RNases and 4% (w/v) paraformaldehyde. The hybridiza- tion solution contained 15 μl of Formamide, 6 μl of 50% Dextran Sulfate, 3 μl of 20X SSC, 1 μl of Salmon DNA (10 mg/ml), 1μl of 10% SDS, and 50 ng of each 5s and 45s rDNA probe, with a final volume of 30 μl. This solu- tion was applied to the chromosome preparations, and the hybridization program was as follows: 75 °C for 7 minutes, 55 °C for 6 minutes, 45 °C for 5 minutes, and 37 °C for 12 hours inside a hybridizer (Biobase, HS-500). After the hybridization, the following washes were per- formed to remove nonspecific binding: 2X SSC at 42 °C for 5 minutes, 20% formamide in 0.1X SSC at 42 °C for 10 minutes, 0.1X SSC at 42 °C for 5 minutes, 2X SSC for 5 minutes at 42 °C, and finally three washes with 0.2% (v/v) Tween 20 in 4X SSC for 5 minutes at room tem- perature. The 5s probe was detected with a Neutravidin- Oregon-Green 488 conjugate (Thermo Scientific™) while the 18s probe was detected with Anti-Digoxigenin-Rho- damine (Roche). The slides were mounted with Slow- Figure 1. Map of Peru showing sampling locations for wild and cul- tivated populations of Physalis peruviana L. 126 Marlon Garcia Paitan et al. Fade™ Gold Antifade Mountant (Invitrogen™), which contained DAPI and an antifade solution. The slides were observed and photographed under an epifluorescence microscope (ZEISS Axio Scope.A1). For DAPI f luorophore, BP 340/30 excitation and BP 510/90 emission filters were used; for Oregon Green 488, BP 470/40 excitation and BP 540/50 emission filters were used; and for Rhodamine, BP 560/40 excitation and BP 630/75 emission filters were used. We specifically worked with cells in metaphase that contained 48 recognizable chromosomes to avoid variation in the results attributa- ble to any somatic aneuploidy present in the meristematic tissue of the root of the species, a phenomenon already observed in prior studies (Carbajal et al. 2021; Franco et al. 2021). The following programs were utilized: GIMP 2.10.14 was used for picture overlaying and chromosomal individualization; IdeoKar1.2 (Mirzaghaderi and Mar- zangi 2015) for morphological measurements of chromo- somes and the production of ideograms; and ImageJ for fluorescence quantification of probe signals. The latter was achieved in accordance with Fitzpatrick (2021). 2.5 Determination of nuclear DNA content Each wild and cultivated population had eight plants evaluated. These were obtained after a three-month seed culture in pots. Flow cytometry was used to determine the nuclear genome size of each plant in duplicate using Pisum sativum cv. ‘Ctirad’ (2C = 9.09 pg DNA) as an internal ref- erence standard. The nuclear suspension preparation pro- tocol and nuclear DNA content estimation were performed as described by Doležel et al. (2007). Young leaves of the standard and goldenberry were utilized as plant material in the streamlined two-step process for nuclei suspension preparation. Furthermore, propidium iodide was employed as a fluorochrome. The nuclear DNA content was estimat- ed using an Attune NxT flow cytometer (Thermo Fisher Scientific) and the following formula: 2C value of the sample (pg de ADN) = !"#$ &'()*)'$ '+ *," -. &"#/ '+ *," (#0&1" !"#$ &'()*)'$ '+ *," -. &"#/ '+ *," 2"+"2"$3" (*#$4#24 x 9.09pg 3. RESULTS 3.1 Number of 5s and 45s rDNA signals in wild and culti- vated populations FISH was used to identify the 5s and 45s rDNA probe signals in the metaphases of Physalis peruvi- ana L. populations (Figure 2). For each population, 25 metaphases with 48 chromosomes were analyzed. After studying the metaphases of all the populations, a total of five combinations of the number of 5s and 45s rDNA sites were identified; three of these combinations were detected in wild populations (Figure 2A, B, E, F, I, J) and four combinations in cultivated populations (Figure 2C, D, E, G, H, K, L). There were no significant variations in the number of 5s and 45s rDNA sites across wild popu- lations (p=0.422), nor between cultivated populations (p=0.085), however, there were significant differences across populations from the same region (p<0.01). Fur- thermore, it was discovered that the predominant rDNA combination in wild populations was six 5s rDNA sites and four 45s rDNA sites, whereas in cultivated popula- tions it was six 5s rDNA sites and two 45s rDNA sites (Figure 3). In general, a higher frequency of six 5s rDNA sites is observed in all goldenberry populations, while for 45s rDNA a number of two sites predominates for cultivated populations and 4 sites for wild populations. 3.2 Characterization of chromosomes with rDNA loci The 12 best metaphases with clear and distinct rDNA signals in relation to their chromosomal arms and fluorescent signals were selected from the 25 metaphases per population, considering at least one metaphase that showed each combination of the number of 5s and 45s rDNA sites from each wild and cultivated population. The morphological characterization, individualization, and pairing with their homologous chromosomes that displayed rDNA signals were performed in each of the selected metaphases (Figure 4, Figure S1). Based on the study of the chromosomes that showed rDNA signals in all populations, nine types of chromosomes were identi- fied according to their morphological features, the posi- tion of the 5s or 45s rDNA locus, the fluorescence inten- sity of the rDNA probe, and their presence in the popu- lations (Figure 5 and Table 1). The N chromosomes are those that are found in all populations: N1 has a meta- centric morphology and the 5s rDNA in the p arm; N2 is submetacentric and has the 45s rDNA in the p arm, and N3 is acrocentric and has the 5s rDNA in the q arm. The S chromosomes, which stand for wild, are found specifically in wild populations: S1 has a submetacentric morphology and 45s rDNA in the q arm; S2 is metacen- tric and has 45s rDNA in the q arm; S3 is metacentric and has 5s rDNA in the p arm. It should be noted that, while N1 and S3 are described in the same way, the dif- ference between them is determined by the length of the chromosome (Table 1). C chromosomes are those found solely in cultivated populations: C1 has a submetacentric 127Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in Physalis peruviana L. morphology and has the 5s rDNA in the q arm, whereas C2 has a metacentric/submetacentric morphology and has the 5s rDNA in the q arm, and a lower fl uorescence intensity than C1. Th e morphology of the C2 chromo- some is attributable to the fact that only one C2 chromo- Figure 2 Fluorescent in situ hybridization signals of the 5s (green) and 45s (red) rDNA probes in Physalis peruviana L. metaphase chromo- somes. Th e numbers at the bottom left of each image represent the number of 5s (green) and 45s (red) sites found in the metaphases. Com- binations of the number of 5s and 45s rDNA sites identifi ed in the population of wild Ayacucho are shown in A, E, and I; wild Cajamarca is shown in B, F, and J; cultivated Ayacucho is shown in C, G, and K; and Cultivated Cajamarca is shown in D, E, H, and L. Th e scale bar measures 10 μm. Figure 3 Th e frequency of 5s and 45s rDNA sites observed in the 25 metaphases of each goldenberry population. Diff erent letters at the top of each frequency circle show signifi cant diff erences (Fish- er’s Exact Test, p<0.05). Figure 4 Chromosomes that showed hybridization of the 5s and 45s rDNA probes between the best 12 metaphases for each popula- tion, encompassing at least one metaphase for each of the combi- nations of the number of 5s and 45s rDNA sites reported for each population of goldenberry. m=metacentric, sm=submetacentric, acro=acrocentric. 128 Marlon Garcia Paitan et al. some was observed in each of the cultivated populations, resulting in a metacentric morphology in Ayacucho and a submetacentric morphology in Cajamarca (Figure 6). The CC chromosome, found only in the Cultivated Cajamarca population, has a submetacentric morphology and the 45s rDNA in the p arm, similar to N2, although it differs in terms of chromosome length and rDNA probe fluorescence intensity (Table 1). The types of chromosomes that contain rDNA are conserved among wild populations. However, there is a difference in the observed frequency of chromosomes S1, which is higher in Cajamarca, and S2, which is higher in Ayacucho (Figure 6). Additionally, in Ayacucho, the 45s rDNA locus of S1 chromosome is found in the cen- tromeric position, whereas in Cajamarca, it is found in the interstitial position. The CC chromosome was found only in Cajamarca among the cultivated populations, while the other chromosomes were found in both groups with no variations in frequency or position of the rDNA (Figure 6). 3.3 Size of the nuclear genome All f low cy tometric analyses showed high-reso- lution histograms with a coefficient of variation (CV) of the G0/G1 peaks between 1.63% and 2.85% (mean 2.04%). Representative histograms are shown with the peaks corresponding to the G0/G1 nuclei of Physa- lis peruviana L. and the internal standard Pisum sati- Figure 5 Characterization of the nine types of chromosomes that showed rDNA probe hybridization based on their existence in populations, morphology, size, presence of the 5s or 45s locus, posi- tion of the rDNA locus, and rDNA probe fluorescence intensity, m=metacentric, sm=submetacentric, and acro=acrocentric. Figure 6 The average ideogram of the types of chromosomes that included rDNA. The proportion observed in the total of the meta- phases analyzed by each population is indicated beneath each chromosome. Equal symbols above the percentages indicate a significant difference between the observed frequencies of both populations (Fisher’s Exact Test, p<0.05). m=metacentric, sm=submetacentric, and acro=acrocentric. 129Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in Physalis peruviana L. vum cv. Ctirad of the wild and cultivated populations in Figure 7. The nuclear DNA estimation content based on the amount of the 2C internal standard (9.09pg of DNA) displayed a substantial variation between both groups (Table 2). 4. DISCUSSION The determination of the number of rDNA sites and their distribution on chromosomes by FISH has proven to be a reliable molecular cytogenetic marker when establishing genetic relationships of plant species that contain a significant number of small and homog- enous chromosomes (Su et al. 2020). The current study Table 1. Morphometric and fluorescence data of the nine types of chromosomes found in Physalis peruviana L. populations. rDNA-bearing chromosome n Chromosome Length Arm ratio Log (DNA probe fluorescence intensity) CM Position of rDNA locus N1 48 3.120 ± 0.416 1.363 ± 0.161 3.943 ± 0.265 m 5s -> p N2 48 2.436 ± 0.332 2.191 ± 0.265 3.909 ± 0.404 sm 45s -> p N3 45 1.499 ± 0.230 3.919 ± 0.641 3.078 ± 0.307 acro 5s -> q S1 10 2.516 ± 0.341 2.189 ± 0.240 3.383 ± 0.318 sm 45s -> q S2 12 2.417 ± 0.216 1.471 ± 0.112 3.371 ± 0.164 m 45s -> q S3 24 2.241 ± 0.287 1.284 ± 0.167 3.995 ± 0.319 m 5s -> p C1 24 3.002 ± 0.461 2.220 ± 0.292 3.930 ± 0.240 sm 5s -> q C2 1 2.908 ± 0.106 1.951 ± 1.238 3.180 ± 0.001 m/sm 5s -> q CC 2 1.922 ± 0.047 2.027 ± 0.366 3.212 ± 0.062 sm 45s -> p The values are expressed as mean ± standard deviation. The “n” sample values are per chromosomal pair. CM = chromosome morphology; m = metacentric; sm = submetacentric; acro= acrocentric. Figure 7 Fluorescence histograms of the nuclei of goldenberry and Pisum sativum cv. Ctirad populations (2C = 9.06 pg as internal reference standard) were analyzed simultaneously. Each peak denoted by the numbers 1 or 2 corresponds to the populations of nuclei in the G0/G1 phase of each species. Each histogram includes the percentage of the coefficient of variation (CV) and average absolute fluorescence for each of these peaks. 130 Marlon Garcia Paitan et al. found a substantial difference in the number of 5s and 45s rDNA sites between wild and cultivated populations of goldenberry (Figure 3). This is the first mapping of the 45s rDNA in Physalis peruviana L., where a number of two, four, and six sites have been reported for all the populations, prevailing a number of four sites in wild populations and two sites in cultivated populations. This intraspecific variation at the species level, as well as its variability among the populations analyzed, in terms of the number of 45s rDNA sites, can be explained by its nature as a fragile location within the plant genome (Huang et al. 2012). This trait increases the likelihood of chromosomal breakage in the rDNA region, resulting in a chromosomal rearrangement. Furthermore, because of its repetitive nature, it is an unstable genomic region that promotes homologous recombination (Rosato et al. 2016), resulting in increased variability in the amount of 45S rDNA sites within the genome. This variabil- ity has also been observed in other Solanaceae species, such as Solanum spp., which presents between 2 and 4 sites (Pendinen et al. 2008; Rego et al. 2009; Moyetta et al. 2017); Capsicum spp., which presents between 2, 4, 6, 8 up to 16, 24, 28, 36 sites (Youn-Kyu et al. 1999; Kwon and Kim 2009; Romero-da et al. 2017); Nicotiana spp. likewise shows considerable variety, reporting between 2, 4, 6, and, to a lesser extent, 8 and 10 sites (Lim et al. 2000; Nakamura et al. 2001; Kitamura et al. 2001; Matyasek et al. 2003; Kovarik et al. 2004). All of this suggests that the number of 45s rDNA sites of 2, 4, and 6 reported in the populations studied in this research is within the predicted range for the Solanaceae fam- ily. The variation between wild and cultivated popula- tions was influenced by the unstable character of the 45s rDNA region and was favored by the selective breed- ing process throughout the domestication of the species (Doebley et al. 2006). In comparison to the number of 45s rDNA sites, the number of 5s rDNA sites has been found to remain reasonably consistent throughout most angiosperm and gymnosperm taxa (Garcia et al. 2017). This is consist- ent with the findings of the current study, which found a predominance of six 5s rDNA sites in all goldenberry populations, with a small fraction of four and seven sites in the cultivated populations (Figure 3). Similarly, Siles et al. (2021) discovered a prevalence of six 5s rDNA sites in goldenberry cultivated populations. However, other Solanaceae species have a lower number of 5s rDNA sites, such as Solanum spp., which has a prevalence of two 5s rDNA sites and, to a lesser extent, four sites (Pendinen et al. 2008; Rego et al. 2009; Aguilera et al. 2016; Romero-da et al. 2017), Capsicum spp., which typi- cally presents two sites (Youn-Kyu et al. 1999; Park et al. 2000; Kwon and Kim 2009; Aguilera et al. 2016; Rome- ro-da et al. 2017); Nicotiana spp., which generally alter- nates between two and four sites (Nakamura et al. 2001; Kitamura et al. 2001; Fulneček et al. 2002; Matyasek et al. 2003; Kovarik et al. 2004), and Cestrum spp., which has two 5s rDNA sites (Fregonezi et al. 2006; Fernandes et al. 2009; Urdampilleta et al. 2014). These data indicate that goldenberry populations have more 5s rDNA sites than other species in the family. However, not enough studies have been conducted on this clade or the Physa- lis genus to be conclusive. Furthermore, the presence of a considerable number of 5s rDNA sites may be due to ribosomal gene copy number amplification during cross- ing over or transposition events (Kapitonov and Jurka 2003; Su et al. 2020). In accordance to prior research (Garcia et al. 2017), the majority of angiosperm spe- cies have more 45s rDNA sites than 5s rDNA sites; this is also shown with molecular cytogenetic results in the Solanaceae family to a higher extent (Vitales et al. 2017). This contrasts with the findings in the goldenberry populations analyzed in this study, which revealed six 5s rDNA sites and two/four 45s rDNA sites (Figure 3). Therefore, these results will be helpful as precedents for the molecular cytogenetic characterization of the genus Physalis and the cytotaxonomic understanding of the Solanaceae family. The nine types of chromosomes that contain rDNA (Figure 5) allowed cytogenetic distinction of wild and cultivated populations of goldenberries (Figure 6). These discrepancies are indistinguishable when only the chro- mosomal number (2n=48) is taken in consideration. Therefore, FISH significantly reduces the number of chromosomes that must be studied to determine cytoge- Table 2. Flow cytometry was used to quantify the nuclear DNA content and genome size of wild and cultivated populations of Physalis peruviana L. using Pisum sativum cv. Ctirad as the internal reference standard. Population n(R) Average Values CV (%)Nuclear DNA content 2C ± DE (pg) Genome size 1C ± DE (x 109 pb)** Wild 8(2) 12.955 ± 0.086* 6.335 ± 0.041* 2.124±0.360 Cultivated 13.262 ± 0.087* 6.485 ± 0.042* 1.960±0.216 The n represents the sample number, while the R represents the number of repetitions per sample, CV: The coefficient of variation of G0/G1 peaks in flow cytometry histograms. * Indicates a significant difference between values of the same col- umn p < 0.05. ** 1pg DNA equal to 0.978×109 bp, according to Doležel et al. (2007). 131Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in Physalis peruviana L. netic differences, emphasizing its relevance in the study of plant species with multiple chromosomes (Su et al. 2020). The existence of different chromosomes in wild (S1, S2, and S3) and cultivated (C1, C2, and CC) popu- lations could be attributed to multiple breeding events that happened throughout the domestication of the spe- cies, leading to chromosomal rearrangements (Bashir et al. 2018; Su et al. 2020). There is no variation in the presence of rDNA-containing chromosomes between the two wild populations, implying that there is no struc- ture between these populations. However, discrepancies in the frequency of chromosomes S1 and S2 may imply a slight genetic distinction between the two wild popula- tions as a result of their geographical separation (Figure 1). The presence of the CC chromosome in Cajamarca could be explained by the same trait found in cultivated populations (Figure 6). The 5s rDNA locus is present in three different chromosomal sites: telomeric (N1 and S3), interstitial (C1 and C2), and centromeric (N3) (Figure 5). The dispersed distribution of 5s rDNA has already been observed in numerous mappings of plant chromo- somes (Vitales et al. 2017), which could be linked to the activity of mobile genetic elements such as transposons, which have been detected in association with riboso- mal gene sequences (Kapitonov and Jurka 2003; Raski- na et al. 2004). The 45s rDNA, on the other hand, has a more restricted position, with telomeric (N2 and CC) and interstitial (S1 and S2) sites reported (Figure 6). This more restricted variability is typical of angiosperms, and it has also been revealed that the 45s rDNA ancestral location is terminal (Garcia et al. 2017). The 45s rDNA locus is known to be involved in the creation of nucleoli during the cell cycle, especially if it is positioned in the satellite sections of the chromosomes since it correlates with the existence of nucleolar organizing areas (Long and Dawid 1980; Lopez et al. 2021). If the species has a large number of 45S sites, however, not all of them will be functional (Grabiele et al. 2018; Báez et al. 2020). In the current investigation, no satellites correlated with an active 45s rDNA locus were found in the analyzed chromosomes, however, the N2 chromosome is likely to contain a functional locus because it is conserved in all goldenberry populations and is the only type of chromo- some that has a 45s rDNA locus in the Ayacucho culti- vated population. Garcia et al. (2017) propose that if a karyotype has a single 5s or 45s rDNA locus, that locus must be functional. The fluorescence intensity of the rDNA probes that are highlighted in the differentiation of chromosome types C1 and C2, as well as between CC and N2, could be related to the number of rDNA tandem repeats that they have between the loci, implying that low fluores- cence would indicate a comparatively low number of repeats (Prado et al. 1996). Furthermore, events such as amplification, deletion, and unequal crossing over are known to change the number of repeats and result in variations in fluorescence signals (Su et al. 2020). Differences in the amount of nuclear DNA between wild and cultivated populations of goldenberries may be due to the domestication process of the species, since artificial selection during domestication affects the evo- lution of its genome (Díez et al. 2013). The results report- ed in this study (Table 2) for the wild (12,955 pg) and cultivated (13,262 pg) populations are higher than those reported by Liberato et al. (2014) in Colombian acces- sions (between 5.77 pg and 8.12 pg). The values of the cultivated populations in this study are remarkably close to those published by Trevisani et al. (2018) in Colom- bian (13.29 pg), Brazilian (13.32 pg), and Peruvian popu- lations (13 pg). It is important to note that all of these studies report a 2n=48 chromosome number. This could imply that they are related to the same population of goldenberries, however, more research into the molecu- lar cytogenetics of these groups is needed to prove it. According to the plant genome size database (Pellicer and Leitch 2020), estimations of the amount of 2C DNA for the Solanaceae family are 5.68 ± 5.27 pg. This would place the Physalis peruviana L. populations studied here in the same family as the Solanaceae species with large genome sizes. Expansion of transposons, particu- larly retrotransposons with lengthy terminal repeats, has been identified as one of the main causes of genome size disparities in plants (Michael 2014), in addition to genome doubling events during speciation (Wendel et al. 2016). Based on the amount of nuclear DNA content in the goldenberry, all of our findings would be indicative of potential biodiversity and should be considered for future genomic investigations. This is the first study in Peru to use molecular cytogenetics and genome size to compare wild and cul- tivated goldenberry populations. In conclusion, the molecular cytogenetic technique revealed a genetic vari- ation in the number of 45s rDNA sites between wild and cultivated populations, as well as different types of chro- mosomes containing rDNA. This genetic difference was also detected when the amount of nuclear DNA in the populations was compared. Finally, the findings show no difference between populations from different places, both for cultivated and wild, suggesting that they probably originated from the same population. This study also underlines the util- ity of these methodologies for analyzing and characteriz- ing the genetic variability of Physalis peruviana L. popu- lations, and it will be valuable for future genetic, genom- 132 Marlon Garcia Paitan et al. ic, and phylogenetic research on this species, as well as the design of genetic improvement programs. GEOLOCATION INFORMATION The cultivated populations of goldenberry were collected from the province of Huanta (Department of Ayacucho) (GPS: 13°01’50.9”S, 74°10’ 14.3”W) and the province of San Pablo (Department of Cajamarca) (GPS: 7°05’43.9”S, 78°49’13.9”W), the wild popula- tions from the province of Huamanga (Department of Ayacucho) (GPS: 13°03’53.5”S, 74°09’13.1”W) and San Marcos (Department of Cajamarca) (GPS: 7°20’47.3”S, 78°06’0.3”W). The research procedure was developed in the Faculty of Biological Sciences of the UNMSM, Lima (GPS: 12°03’35.1”S, 77°04’55.6”W). ACKNOWLEDGMENTS We gratefully acknowledge the assistance of Ing. Gean Carlo Ciprian Salcedo of the Program for Research and Social Projections in Cereals and Native Grains of the Universidad Nacional Agraria La Molina in measur- ing the genome size using flow cytometry. The authors would like to express their gratitude to the AgroAndino company in Cajamarca and the Andrea family in Ayacu- cho for providing us with goldenberry samples. Finally, we would like to express our gratitude to the UNMSM Vice Rectorate for Research and Postgraduate Studies for providing study financing. FUNDING The Vice Rectorate for Research and Postgraduate Studies at the National University of San Marcos sup- ported this research under the Research Projects Pro- gram for Research Groups (N°. RR-03202-R-18, project code B18100191) and the Program for the Promotion of Undergraduate Thesis. (N°. RR-4692-19, project code B19100214). REFERENCES Aguilera PM, Debat HJ, Scaldaferro MA, Martí DA, Gra- biele M. 2016. FISH-mapping of the 5S rDNA locus in chili peppers (Capsicum-Solanaceae). Anais da Academia Brasileira de Ciências. 88(1): 117-125. Aliyeva-Schnorr L, Ma L, Houben A. 2015. A fast air- dry dropping chromosome preparation method suit- able for FISH in plants. Journal of Visualized Experi- ments. 106: e53470. Azeez S, Faluyi JO. 2019. Karyotypic studies of four Phys- alis species from Nigeria. Acta Botánica Hungarica. 61(1-2): 5-9. Báez M, Souza G, Guerra M. 2020. Does the chromosom- al position of 35S rDNA sites influence their tran- scription? A survey on Nothoscordum species (Ama- ryllidaceae). Genetics and molecular biology. 43(1): e20180194. Bashir T, Chandra Mishra R, Hasan MM, Mohanta TK, Bae H. 2018. Effect of hybridization on somatic mutations and genomic rearrangements in plants. International journal of molecular sciences. 19(12): 3758. Carbajal Y, Bonilla H, Siles-Vallejos M, López A. 2021. Comparative cytogenetics of Physalis peruviana in three cultivated populations from Cajamarca, Peru. Revista peruana de biología. 28(2):e20462. Ciprian-Salcedo GC, Jimenez J, Zolla G. 2020. Flow cytometry applications in plant breeding. Revista Peruana De Biología. 27(1): 079-084. Díez CM, Gaut BS, Meca E, Scheinvar E, Montes-Her- nandez S, Eguiarte LE, Tenaillon MI. 2013. Genome size variation in wild and cultivated maize along alti- tudinal gradients. The new phytologist. 199(1): 264– 276. Doebley JF, Gaut BS, Smith BD. 2006. The molecular genetics of crop domestication. Cell. 127(7): 1309– 1321. Doležel J, Greilhuber J, Suda J. 2007. Estimation of nucle- ar DNA content in plants using flow cytometry. Nature Protocols. 2(9): 2233–2244 Fernandes T, de Almeida Rego L do NA, Nardy M, Yuy- ama PM, Vanzela ALL. 2009. Karyotype differentia- tion of four Cestrum species (Solanaceae) revealed by fluorescent chromosome banding and FISH. Genetics and molecular biology. 32(2): 320–327. Fitzpatrick M. 2021. The Open Lab Book. Release 1.0. Readthedocs. p. 50-53;[accessed 2022 Apr 24]. htt- ps://buildmedia.readthedocs.org/media/pdf/theolb/ latest/theolb.pdf Franco CV, Liberato Guio SA, Sanchez Betancourt EP, García Arias FL, Nuñez Zarantes VM. 2021. Cytoge- netic and cytological analysis of Colombian cape gooseberry genetic material for breeding purposes. Caryologia. 74(3): 21-30. Fregonezi JN, Fernandes T, Torezan JMD, Vieira AOS, Vanzela ALL. 2006. Karyotype differentiation of four Cestrum species (Solanaceae) based on the physical mapping of repetitive DNA. Genetics and molecular biology. 29(1): 97–104. 133Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in Physalis peruviana L. Fulneček J, Lim KY, Leitch AR, Kovařík A, Matyášek R. 2002. Evolution and structure of 5S rDNA loci in allotetraploid Nicotiana tabacum and its putative parental species. Heredity. 88(1): 19-25. Garcia S, Kovařík A, Leitch AR, Garnatje T. 2017. Cytogenetic features of rRNA genes across land plants: analysis of the Plant rDNA database. The Plant journal: for cell and molecular biology. 89(5): 1020–1030. Grabiele M, Debat HJ, Scaldaferro MA, Aguilera PM, Moscone EA, Seijo JG, Ducasse DA. 2018. Highly GC-rich heterochromatin in chili peppers (Capsicum -Solanaceae): A cytogenetic and molecular character- ization. Scientia Horticulturae. 238: 391–399. Hadziavdic K, Lekang K, Lanzen A, Jonassen I, Thomp- son EM, Troedsson C. 2014. Characterization of the 18S rRNA gene for designing universal eukaryote specific primers. PLoS One. 9(2):e87624. Herrera JC. 2007. La citogenética molecular y su apli- cación en el estudio de los genomas vegetales. Agronomía colombiana. 25(1): 26–35. Huang M, Li H, Zhang L, Gao F, Wang P, Hu Y, Yan S, Zhao L, Zhang Q, Tan J, Liu X, He S, Li L. 2012. Plant 45S rDNA clusters are fragile sites and their instability is associated with epigenetic alterations. PLoS One. 7(4): e35139. Jedrzejczyk I, Rewers M. 2020. Identification and genetic diversity analysis of edible and medicinal Malva spe- cies using flow cytometry and ISSR molecular mark- ers. Agronomy. 10(5): 650. Kapitonov VV, Jurka J. 2003. A novel class of SINE ele- ments derived from 5S rRNA. Molecular biology and evolution. 20(5): 694–702. Kitamura S, Inoue M, Shikazono N, Tanaka A. 2001. Relationships among Nicotiana species revealed by the 5S rDNA spacer sequence and fluorescence in situ hybridization. Theoretical and applied genetics. 103(5): 678–686. Kovarik A, Matyasek R, Lim KY, Skalická K, Koukalová B, Knapp S, Chase M, Leitch AR. 2004. Concerted evolution of 18-5.8-26S rDNA repeats in Nicotiana allotetraploids. Biological journal of the Linnean Society. Linnean Society. 82(4): 615–625. Kwon J-K, Kim B-D. 2009. Localization of 5S and 25S rRNA genes on somatic and meiotic chromosomes in Capsicum species of chili pepper. Molecules and Cells. 27(2): 205–209. Liberato S, Sánchez-Betancourt E, Argüelles JH, González C, Núñez VM, Barrero LS. 2014. Cytogenetics of Physalis peruviana L. and Physalis floridana Rydb. genotypes with differential response to Fusarium oxysporum. Corpoica Ciencia & Tecnología Agro- pecuaria. 15(1): 51-61. Lim KY, Matyásek R, Lichtenstein CP, Leitch AR. 2000. Molecular cytogenetic analyses and phylogenetic studies in the Nicotiana section Tomentosae. Chro- mosoma. 109(4): 245–258. Long EO, Dawid IB. 1980. Repeated genes in eukaryotes. Annual review of biochemistry. 49(1): 727–764. Lopez FB, Fort A, Tadini L, Probst AV, McHale M, Friel J, Ryder P, Pontvianne FDR, Pesaresi P, Sulpice R, et al. 2021. Gene dosage compensation of rRNA transcript levels in Arabidopsis thaliana lines with reduced ribo- somal gene copy number. The plant cell. 33(4): 1135– 1150. Matyasek R, Lim KY, Kovarik A, Leitch AR. 2003. Ribo- somal DNA evolution and gene conversion in Nico- tiana rustica. Heredity. 91(3): 268–275. Michael TP. 2014. Plant genome size variation: bloating and purging DNA. Briefings in functional genomics. 13(4): 308–317. Mirzaghaderi G, Marzangi K. 2015. IdeoKar: an ideo- gram constructing and karyotype analyzing software. Caryologia. 68(1)31-35. Moyetta NR, Urdampilleta JD, Chiarini FE, Bernardello GL. 2017. Heterochromatin and rDNA patterns in Solanum species of the Morelloid and Dulcamaroid clades (Solanaceae). Plant biosystems. 151(3): 539– 547. Nakamura R, Kitamura S, Inoue M, Ohmido N, Fukui K. 2001. Karyotype analysis of Nicotiana kawakamii Y. Ohashi using DAPI banding and rDNA FISH. Theo- retical and applied genetics. 102: 810–814. Park YK, Park KC, Park CH, Kim NS. 2000. Chromo- somal localization and sequence variation of 5S rRNA gene in five Capsicum species. Molecules and Cells. 10(1): 18–24. Pellicer J, Hidalgo O, Dodsworth S, Leitch IJ. 2018. Genome size diversity and its impact on the evolu- tion of land plants. Genes (Basel). 9(2): 88. Pellicer J, Leitch IJ. 2020. The Plant DNA C-values data- base (release 7.1): an updated online repository of plant genome size data for comparative studies. New Phytologist. 226(2): 301-305. Pendinen G, Gavrilenko T, Jiang J, Spooner DM. 2008. Allopolyploid speciation of the Mexican tetraploid potato species Solanum stoloniferum and S. hjertingii revealed by genomic in situ hybridization. Genome. 51(9): 714-20. Poggio L, Confalonieri V, Comas C, Gonzalez G, Naranjo CA. 2000. Evolutionary relationships in the genus Zea: analysis of repetitive sequences used as cytologi- cal FISH and GISH markers. Genetics and Molecular Biology. 23(4):1021–1027. 134 Marlon Garcia Paitan et al. Prado EA, Faivre-Rampant P, Schneider C, Darmency MA. 1996. Detection of a variable number of riboso- mal DNA loci by fluorescent in situ hybridization in Populus species. Genome. 39(5): 1020–1026. Raskina O, Belyayev A, Nevo E. 2004. Activity of the En/ Spm-like transposons in meiosis as a base for chro- mosome repatterning in a small, isolated, periph- eral population of Aegilops speltoides Tausch. Chro- mosome research: an international journal on the molecular, supramolecular and evolutionary aspects of chromosome biology. 12(2): 153–161. Rego LN, da Silva CRM, Torezan JM, Gaeta ML, Vanzela AL. 2009. Cytotaxonomical study in Brazilian species of Solanum, Lycianthes and Vassobia (Solanaceae). Plant systematics and evolution. 279: 93–102. Rodríguez NC, Bueno ML. 2006. Study of the cytogenetic diversity of Physalis peruviana L. (Solanaceae). Acta Biológica Colombiana, Bogotá. 11(2): 75-85. Romero-da MV, Urdampilleta JD, Forni ER, Moscone EA. 2017. Cytogenetic markers for the characteriza- tion of Capsicum annuum L. cultivars. Plant Bio- systems - An International Journal Dealing with all Aspects of Plant Biology. 151(1): 84-91. Rosato M, Kovařík A, Garilleti R, Rosselló JA. 2016. Con- served organisation of 45S rDNA sites and rDNA gene copy number among major clades of early land plants. PloS one. 11(9): e0162544. Salim D, Gerton JL. 2019. Ribosomal DNA instability and genome adaptability. Chromosome research: an international journal on the molecular, supramolecu- lar and evolutionary aspects of chromosome biology. 27(1–2): 73–87. Sánchez EP. 2014. Ploidy Level of Cape Gooseberry Plants from Anther Cultivation. [master’s thesis]. Bogotá: Universidad Nacional de Colombia. Sierra y Selva Exportadora. 2021. Analysis of the Gold- enberry Market from 2015 to 2020. Peru: Unidad de Inteligencia Comercial; 9-18. Siles M, Bracamonte O, García M, López A. 2021. The first report on the identification of the 5s rDNA locus in Physalis peruviana L. chromosomes. Scientia Agr- opecuaria. 12(2): 149-153. Singh N, Singh S, Maurya P, Arya M, Khan F, Dwivedi DH, Saraf SA. 2019. An updated review on Physa- lis peruviana fruit: Cultivational, nutraceutical and pharmaceutical aspects. Indian Journal of Natural Products and Resources. 10(2): 97-110. Su D, Chen L, Sun J, Zhang L, Gao R, Li Q, Han Y, Li Z. 2020. Comparative chromosomal localization of 45S and 5S rDNA sites in 76 purple-fleshed sweet potato cultivars. Plants. 9(7): 865. Trevisani N, Melo, de Melo RC, Oliveira PM, Colli MP, Meirelles JL, Frederico A. 2018. Ploidy and DNA content of cape gooseberry populations grown in southern Brazil. Caryologia. 71(4): 414–419. Urdampilleta J, Chiarini F, Stiefkens L, Bernardello G. 2014. Chromosomal differentiation of Tribe Cestreae (Solanaceae) by analyses of 18-5.8-26S and 5S rDNA distribution. Plant Systematics and Evolution. 301(5): 1325–1334. Vitales D, D’Ambrosio U, Gálvez F, Kovařík A, Garcia S. 2017. Third release of the plant rDNA database with updated content and information on telomere com- position and sequenced plant genomes. Plant System- atics and Evolution. 303(8): 1115–1121. Volkov RA, Zanke C, Panchuk II, Hemleben V. 2001. Molecular evolution of 5S rDNA of Solanum species (sect. Petota): application for molecular phylogeny and breeding. Theoretical and Applied Genetics. 103: 1273–1282. Wendel JF, Jackson SA, Meyers BC, Wing RA. 2016. Evo- lution of plant genome architecture. Genome biology. 17(1): 37. Youn-Kyu P, Kim B-D, Kim B-S, Armstrong KC, Kim N-S. 1999. Karyotyping of the chromosomes and physical mapping of the 5S rRNA and 18S-26S rRNA gene families in five different species in Capsicum. Genes & genetic systems. 74(4): 149–157. ONLINE SUPPLEMENTARY MATERIAL Figure S1. Chromosomes from the 12 best metaphases among the populations of goldenberries studied. https://drive.google.com/file/d/1FzgeeRgtUxS2GkD588N8m3cSwzF 8Ss1_/view?usp=sharing Caryologia International Journal of Cytology, Cytosystematics and Cytogenetics Volume 75, Issue 3 - 2022 Firenze University Press Chromosome Mapping of Repetitive DNAs in the Picasso Triggerfish (Rhinecanthus aculeatus (Linnaeus, 1758)) in Family Balistidae by Classical and Molecular Cytogenetic Techniques Kamika Sribenja1, Alongklod Tanomtong1, Nuntaporn Getlekha2,* Chromosome number of some Satureja species from Turkey Esra Kavcı1, Esra Martin1, Halil Erhan Eroğlu2,*, Fatih Serdar Yıldırım3 L-Ascorbic acid modulates the cytotoxic and genotoxic effects of salinity in barley meristem cells by regulating mitotic activity and chromosomal aberrations Selma Tabur1,*, Nai̇me Büyükkaya Bayraktar2, Serkan Özmen1 Characterization of the chromosomes of sotol (Dasylirion cedrosanum Trel.) using cytogenetic banding techniques Kristel Ramírez-Matadamas1, Elva Irene Cortés-Gutiérrez2, Sergio Moreno-Limón2, Catalina García-Vielma1,* Contributions of species Rineloricaria pentamaculata (Loricariidae:Loricariinae) in a karyoevolutionary context A Cius¹, CA Lorscheider2, LM Barbosa¹, AC Prizon¹, CH Zawadzki3, LA Borin-Carvalho¹, FE Porto4, ALB Portela-Castro1,4 Cadmium induced genotoxicity and antioxidative defense system in lentil (Lens culinaris Medik.) genotype Durre Shahwar1,2,*, Zeba Khan3, Mohammad Yunus Khalil Ansari1 Biogenic synthesis of noble metal nanoparticles using Melissa officinalis L. and Salvia officinalis L. extracts and evaluation of their biosafety potential Denisa Manolescu1,2, Georgiana Uță1,2,*, Anca Șuțan3, Cătălin Ducu1, Alin Din1, Sorin Moga1, Denis Negrea1, Andrei Biță4, Ludovic Bejenaru4, Cornelia Bejenaru5, Speranța Avram2 Polyploid cytotypes and formation of unreduced male gametes in wild and cultivated fennel (Foeniculum vulgare Mill.) Egizia Falistocco Methomyl has clastogenic and aneugenic effects and alters the mitotic kinetics in Pisum sativum L. Sazada Siddiqui*, Sulaiman A. Alrumman Comparative study and genetic diversity in Malva using srap molecular markers Syamand Ahmed Qadir1, Chnar Hama Noori Meerza2, Aryan Mahmood Faraj3, Kawa Khwarahm Hamafaraj4, Sherzad Rasul Abdalla Tobakari5, sahar hussein hamarashid6,* Nuclear DNA 2C-values for 16 species from Timor-Leste increases taxonomical representation in tropical ferns and lycophytes Inês da Fonseca Simão1, Hermenegildo Ribeiro da Costa1,2,3, Helena Cristina Correia de Oliveira1,2, Maria Helena Abreu Silva1,2, Paulo Cardoso da Silveira1,2,* Nuclear DNA content and comparative FISH mapping of the 5s and 45s rDNA in wild and cultivated populations of Physalis peruviana L. Marlon Garcia Paitan*, Maricielo Postillos-Flores, Luis Rojas Vasquez, Maria Siles Vallejos, Alberto López Sotomayor Identification of genetic regions associated with sex determination in date palm: A computational approach Zahra Noormohammadi1,*, Masoud Sheidai2, Seyyed-Samih Marashi3, Somayeh Saboori1, Neda Moradi1, Samaneh Naftchi1, Faezeh Rostami1 Comparative karyological analysis of some Turkish Cuscuta L. (Convolvulaceae) Neslihan Taşar¹, İlhan Kaya Tekbudak2, İbrahim Demir3, Mikail Açar1,*, Murat Kürşat3 Identifying potential adaptive SNPs within combined DNA sequences in Genus Crocus L. (Iridaceae family): A multiple analytical approach Masoud Sheidai1,*, Mohammad Mohebi Anabat1, Fahimeh Koohdar1, Zahra Noormohammadi2