6santianez-white rot disease.pmd


White Rot Disease and Epiphytism on Halymenia d urvillei

54

SCIENCE DILIMAN  (JANUARY-JUNE 2016) 28:1, 54-60

White Rot Disease and Epiphytism
on Halymenia durvillei Bory de Saint-Vincent
(Halymeniaceae, Rhodophyta) in Culture

W ilfred John E. Santiañez*
University of the Philippines Diliman
Hokkaido University,  Japan

Hera J. Suan-Flandez
University of the Philippines Diliman

Gavino C. Trono Jr.
University of the Philippines Diliman

Keywords:  E p i p h y t e ,  Neosiphonia,  red algae, seaweed culture, seaweed

d i s e a s e

_______________
*Corresponding Author

ISSN 0115-7809 Print / ISSN 2012-0818 Online

Among the targeted seaweed species for resource development in the Philippines

is the red seaweed Halymenia durvillei Bory de Saint-Vincent, which is commonly

known as “red sea lettuce”.  Locally, it is known as lablabig, gayong-gayong, gargarnatis,

gamet, aragantiilek, and guraman (Trono and Ganzon-Fortes 1988). Aside from being

used as food in many countries (Lewmanomont and Kawaguchi 2002), including the

Philippines, H. durvillei is also a source of the red pigment r-phycoerythrin, as well

a s  a  l a m b d a - c a r r a g e e n a n - l i k e  p o l y s a c c h a r i d e  ( F e n o r a d o s o a  e t  a l .  2 0 0 9 ) .

Phycoerythrin is an important food and cosmetic colorant, a therapeutic agent owing

to its immunomodulating and anti-cancer activity, and a fluorescent agent, among

others (Bermejo Román et al. 2002; Spolaore 2006). The current market value for

1 mg of r-phycoerythrin from Porphyra tenera “Nori” is US$ 1,030 (SG$ 1,400;

Sigma-Aldrich Online Catalog, 2016a) Lambda-carrageenan is a type of carrageenan

(an integral part of red algal cell wall), but it only occurs naturally to a few species.

As with other types of carrageenan,  lambda-carrageenan is widely used in the food

industry as an emulsif ier (Fenoradosoa et al. 2009), but it can also act as an allergy

suppressant against cer tain food products (Tsuji et al. 2003). Currently, 5 g of

lambda-carrageenan is priced at US$ 114.79 (SG$ 156; Sigma-Aldrich Online

Catalog, 2016b).



W.J.E. Santiañez et al.

55

In view of the high market value of H. durvillei,  Dr. Gavino C. Trono Jr.  of the Marine

Science Institute, University of the Philippines (UPMSI), in collaboration with the

then Philippine Council for Aquatic and Marine Research and Development (PCAMRD)

of the Depar tment of Science and Technology (DOST ), developed a culture

technology for the sustainable mass production of H. durvillei.  A booklet entitled

‘A Primer on the Land-based Culture of Halymenia durvillaei Bory de Saint Vincent

(Rhodophyta)’ (Trono 2010) was published as a culmination of the research and

development process. However, in a recent work to ref ine the technology on

vegetative culture as well as in developing the spore to sea-out-planting

mariculture of H. durvillei, we encountered two challenges that were detrimental

to the alga’s growth and health: white rot disease and epiphytism. Diseases and

epiphytes are perennial challenges to the culture of seaweeds (e.g. , Eucheuma

denticulatum and Kappaphycus alvarezii),  which often lead to signif icant losses in

biomass and prof it for the farmer.  We describe herein the nature and progression

of the disease, as well as the identity of the epiphytic organism. We also offer

possible explanation for the infestation of epiphytes on H. durvillei.

Figure 1. White rot disease infected sea-out-planted carpospores-cultured Halymenia
durvillei showing discolored and decaying portions of each thallus (arrows). Note
that the circular infection often affects the basal portion of the thallus.



White Rot Disease and Epiphytism on Halymenia d urvillei

56

We described the occurrence and nature of the disease based on the observations

we made on the open sea-out-planted carpospores-cultured H. durvillei thalli grown

at the Bolinao Marine Laboratory (BML) of UPMSI in Guiguiwanen, Bolinao,

Pangasinan. For the land-based (tank) culture of H. durvillei using vegetative

propagules, we used the methods described by Trono (2008), while the methods

utilized on the spore culture to sea-out-planting portion of the project are detailed

in Trono (2014). We determined the identity of the epiphyte based solely on the

morphological characters of ethanol-preserved samples. Epiphytes were stained

with aniline blue and mounted on corn syrup with phenol and were observed under

the light microscope.

White Rot Disease on Open Sea-outplanted
Carpospores-cultured H. d urvillei

The white rot disease appears as a semi-circular spot of discoloration on the surface

of the thallus. The initial site of infection enlarges while becoming progressively

lighter, and its color turns from bright orange to light yellow until it becomes

translucent as pigments appear to disintegrate. The affected part of the thallus

becomes increasingly soft, with the white to translucent area being the most delicate

and often decomposing (Figure 1, arrows). Large and soft infected portions of the

thallus are the parts which facilitate the breakage and the consequent loss of the

distal portion of the thallus. We noted that, in most cases, the infected parts are

found near the base of the thallus. Thus, during rough seas or in the presence of

strong waves or currents, the majority of the thalli is broken and washed away,

considerably reducing the amount of biomass.

The characteristic symptoms of the disease in H. durvillei were similar to the white

rot disease reported in Porphyra, where Vibrio (as Beneckea) was indicated as among

the possible pathogens (Tsukidate 1977).  The discoloration, decay of affected

tissues, and consequent loss of biomass in H. durvillei due to breakage were also

reminiscent of the ice-ice disease common among the carrageenan-producing

eucheumatoids, Kappaphycus and Eucheuma (Trono 1974). Ice-ice disease in

eucheumatoids, in addition to unfavorable environmental conditions, is also

associated with pathogenic bacteria (Uyenco et al. 1981), particularly Vibrio sp.

P11 and Cytophaga sp. P25 (Largo et al. 1995; Largo 2002). We were not able to

conduct further studies on what environmental factors induced the advent of the

disease, but we hypothesize that, as in the case of other seaweed diseases, pathogenic

microorganisms may also be involved in the white rot disease in H. durvillei.



W.J.E. Santiañez et al.

57

Identity of the Epiphyte and Potential Triggers of Epiphytism
on Tank-cultured Vegetative H. durvillei

The thalli of the epiphytes are brownish-red, mostly erect but sometimes prostrate,

and generally less than 3 cm (Figure 2a). The epiphyte’s main axes are attached to

H. durvillei by rhizoids that are cut-off from pericentral cells (Figure 2b). Branching

is pseudodichotomous, with each branch abruptly tapering at the apices (Figure 2f ).

Branch segment has four ecor ticate pericentral cells. Trichoblasts are few,

rudimentary, and limited at the apices. These are quickly shed, leaving spirally

arranged scar cells (Figure 2e, arrows). The species is dioecious. Female

g a m e t o p h y t e s  p r o d u c e  o v o i d  m a t u r e  c y s t o c a r p s  ( F i g u r e  2 c ) ,  w h i l e  m a l e

gametophytes produce spermatia on conical spermatangial branches (immature)

that develop as a trichoblast fork (Figure 2d). Tetrasporophytes produce

Figure 2. Details of the alga, Neosiphonia apiculata, found epiphytic on tank-cultured
Halymenia durvillei. (A) Dried herbarium specimen; (B) Prostrate portion of the
main axis showing rhizoids cut off from the pericentral cells (arrow); (C) Female
plant showing ovoid mature cystocarp; (D) Male plant bearing immature
spermatangial branch (sp) issuing from trichoblast (tr); (E) Portion of the branch
showing spirally arranged scar cells in every segment (arrows); (F) Distal branch
portion showing spiral arrangement of tetraspores and the abrupt apical apices (a,
scale bar = 1cm; b,c, scale bar = 50μm; d-f, scale bar = 100μm).



White Rot Disease and Epiphytism on Halymenia d urvillei

58

tetrasporangia in slightly spiral series, associated with lateral cover cells (Figure

2f ). Despite being relatively larger, the characters of the epiphyte agree with the

original descriptions of the polysiphonous alga described by Hollenberg (1968),

currently known as Neosiphonia apiculata (Hollenberg) Masuda et Kogame

(Ceramiales, Rhodophyceae) (Tani et al. 2003). The polysiphonous alga, N. apiculata

appears to be a common epiphyte affecting cultured seaweeds (e.g. , eucheumatoids

in Calatagan, Batangas and Green Island, Palawan (WJE Santiañez, personal

observation)) but may pose as a threat to seaweed farmers, such as the case of the

heavy epiphytism in Calaguas Is. , Camarines Norte (Hurtado et al. 2006; Vairappan

et al. 2008). Heavy epiphytism by N. apiculata has negatively affected the

development of H. durvillei, resulting in stunted growth, forcing us to prematurely

discontinue our ongoing study.

Moreover, epiphytism became apparent in March 2013. The occurrence of heavy

growth of epiphytes on cultured H. durvillei was preceded by algal blooms in the

area that are often associated with high nutrient fluxes. During the said period,

temperature (29-30°C) and salinity (34 ppt) levels in culture tanks were within

optimum levels, but high water nutrient concentration was observed (ammonia:

2.17-3.87 μM; nitrate: 0.89-6.69 μM; phosphate: 2.13-2.54 μM). We believe that

high nutrient concentrations coupled with warm water temperature and high incident

light during the summer months encouraged the growth and proliferation of

N . apiculata. In eucheumoid culture in the Philippines, incidence of epiphytism by

the alga was also high during summer (Santiañez and Trono, unpublished data).

ACKNOWLEDGMENTS

This study was funded by the Philippines’ Department of Agriculture – Bureau of

Agricultural Research (DA-BAR). The authors wish to acknowledge Mr. Jerry Arboleda

and Mr. Ronaldo de Guzman for their assistance in the conduct of laboratory and

f ield work, Ms. Marilyn Dayao for the administrative help, and Mr. Christian Ace

Guerta for mounting some of the specimens used in this study. This is the UP

Marine Science Institute Contribution No. 449.



W.J.E. Santiañez et al.

59

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_____________

Wilfred John E. Santiañez <santianez@mail.sci.hokudai.ac.jp> was formerly a
Research Associate at the Marine Science Institute of the University of the Philippines
(UP-MSI), Diliman, Quezon City, where he worked on seaweed diversity, ecology,
and culture. He has a master’s degree in Environment and Natural Resource
Management from the University of the Philippines Open University and is now
pursuing his PhD in Natural History Sciences at Hokkaido University in Sapporo,
Japan. His current research is focused on the diversity and molecular phylogeny of
the brown algal genus Hydroclathrus.

Hera J. Suan-Flandez holds a master’s degree in Aquaculture from the University
of Ghent, Belgium and has worked as a Senior Research Assistant at the UP-MSI.
She has conducted ecological as well as spore and vegetative culture studies on
the red alga Halymenia durvillei, which were essential to the ref ining of the culture
technology for this economically important species.

Gavino C. Trono Jr. is a National Scientist at the National Academy of Science and
Technology (NAST )-Philippines and Professor Emeritus of Marine Science at UP-
MSI. Considered as the Father of Modern Philippine Phycology, Dr. Trono has more
than 40 years of contribution to the studies on the diversity (taxonomy), ecology,
and mariculture of seaweed resources of the Philippines.