213

 Research Article

2020 38(2): 213-226 http://dx.doi.org/10.18820/2519593X/pie.v38.i2.14

Published by the UFS
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With Attribution (CC-BY)

CONTEXTUALISING SCIENCE 
AND MATHEMATICS 
TEACHER PROFESSIONAL 
DEVELOPMENT IN RURAL 
AREAS 

ABSTRACT

Science and mathematics teacher professional development in 
South Africa does not adequately address teachers’ pedagogical 
content knowledge or ability to integrate indigenous knowledge 
into the curriculum. This situation is partly due to traditional teacher 
professional development programmes that utilise top-down and 
expert-driven approaches without consulting teachers. This “one-
size-fits-all” model is rarely relevant to teachers’ classroom realities, 
especially in rural areas. The research question that guided this 
research was: How could the professional development intervention 
be contextualised to better meet the educational needs of a rural 
environment? In this paper, we explore the design principles for 
teacher professional development interventions that could address 
the needs of teachers and the context, acknowledging that teachers 
in rural areas face different challenges compared to teachers in 
urban areas. We use the Hantam region of the Northern Cape 
Province as a case study to explore the affordances of partnerships 
with local indigenous knowledge holders and cultural institutions 
(museums) in the professional development of teachers. Data were 
generated from semi-structured interviews with Hantam school and 
community participants using a qualitative approach. Two major 
themes that emerged from this qualitative research was that (a) 
the involvement of indigenous knowledge holders and museums as 
“third partners” in the value chain between universities and schools, 
could greatly assist to better contextualise the “western” science 
curriculum, and (b) the incorporation of indigenous knowledge in 
the STEM curriculum could assist in building the self-esteem of 
learners. We argue that contextualising science and mathematics 
teacher professional development for the rural environment has 
affordances for improving not only teacher competencies, but also 
learners’ views on the relevance of science and mathematics in 
everyday life. 

Keywords: Teacher professional development; contextualised 
curriculum; indigenous knowledge; rural areas; science and 
citizenship education.

1. INTRODUCTION
In South Africa, education is essential for redressing past 
injustices and transforming society into a democratic 

AUTHORS:
Dr Melissa Speight Vaughn1 

Prof Josef de Beer1  

AFFILIATION: 
Research Unit Self-Directed 
Learning, North-West University

DOI: http://dx.doi.
org/10.18820/2519593X/pie.v38.
i2.14

e-ISSN 2519-593X

Perspectives in Education 

2020 38(2): 213-226

PUBLISHED:
04 December 2020

http://dx.doi.org/10.18820/2519593X/pie.v38.i2.14
https://orcid.org/0000-0003-4475-0834
https://orcid.org/0000-0002-2411-6599
http://dx.doi.org/10.18820/2519593X/pie.v38.i2.14
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Perspectives in Education 2020: 38(2)

nation-state. The Department of Education asserts that education is pivotal to economic 
prosperity and plays a key role in enabling citizens to improve the quality of their lives in 
contributing to a peaceful, productive and democratic nation (Department of Education, 2005). 
Positioned at the front lines of educational reform were science, technology, engineering and 
mathematics curriculum reform, of which professional development was a critical component 
(Villegas-Reimers, 2003). In order to be a global player in the world economy, South Africa 
needs innovative and creative scientists, but this means that science education in the country 
has to be greatly improved (Centre for Development and Enterprise, 2011). Conventional 
teacher professional development in the form of workshops, conferences, courses and 
seminars were initiated to improve identified skill deficits in content, curriculum and pedagogy 
(Rogan, 2004; Taylor, 2008; Kriek & Grayson, 2009). However, after two decades, teacher 
competency has not improved as envisaged (Tsotetsi & Mahlomaholo, 2015; De Beer, 2016). 
Researchers note that many professional development programmes are imported products, 
implemented uniformly from a top-down perspective and based on expert knowledge that 
is irrelevant to the classroom realities of teachers, especially in rural areas (Ball & Cohen, 
1999; Bantwini, 2009; Ono & Ferreira, 2010; De Beer, 2016). In this paper we reflect on 
design principles for teacher professional development interventions that could better address 
the needs of teachers and the rural sector. We aim to address the gap between teacher 
professional development and their educational needs by investigating how teachers could 
be assisted to infuse indigenous knowledge into the science and mathematics curricula. This 
research contributes to the national “decolonising of the curriculum” debate by contextualising 
teacher professional development for a rural environment. The research question guiding 
this research was: How could the professional development intervention be contextualised to 
better meet the educational needs of a rural environment?

Many rural schools are located on former homelands, previously disadvantaged areas with 
a multitude of challenges to the achievement of quality education (McKinney, 2005; Stack et al., 
2011). Rural areas represent the poorest and least resourced areas of the country. However, 
science in these contexts is embedded in local indigenous knowledges of the environment 
through generations of observation and experiences (Aikenhead, 1996). De Beer and Mentz 
(2017) have shown that the holders of indigenous knowledge are often, per definition, self-
directed learners who solved problems in their environment through processes very similar 
to the syntactical tools utilised by scientists. Through oral transmission, indigenous ways of 
knowing and practising science – as well as mathematics and technology – are vibrant in 
rural environments (Khupe, 2014). Researchers have documented the influence of cultural 
background on science education (Cameron, 2010; Manzini, 2006) as well as the connection 
between science and citizenship (Irwin & Wynne, 1996; Jasanoff, 2004). This paper explores 
teacher professional development from a community-based approach, recognising that 
schools are integrated into the fabric of rural communities. We explore the affordances of 
partnerships with indigenous knowledge holders and cultural institutions (museums) in the 
professional development of teachers. Similar to Jautse, Thambe and De Beer (2016), we 
allude to the fact that a “third partner” is needed in the value chain between schools and 
university teacher training to effectively prepare science teachers for a complex 21st century. 

2. THEORETICAL FRAMEWORK
This paper views teacher professional development through a socio-cultural lens that 
engages knowledge and cultural assets of the local community. We integrate learning 

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Speight Vaughn & De Beer Contextualising science and mathematics 

theories – namely, social constructivism (Vygotsky, 1978) and embodied, situated and 
distributed cognition (Hardy-Vallee & Payette, 2008) – as a foundation from which to develop 
teachers professionally and promote life-long learning. We argue for a situational approach 
to professional development that considers teacher structures and supports that assist with 
knowledge transfer in classrooms (Darling-Hammond & McLaughlin, 1995; Rout & Behera, 
2014). 

2.1  Social constructivism; and embodied, situated and 
distributed cognition

We argue from the perspective of embodied, situated and distributed cognition (ESDC) that 
grants the body a central role in cognition (Wilson, 2002; Hardy-Vallee & Payette, 2008). 
Cognition is physiologically embodied, socio-culturally situated and distributed among the 
community. ESDC emphasises the connection between brain/mind and ongoing interaction 
with the physical and social environment (Reichelt & Rossmanith, 2008). This cognitive 
system guides action (Wilson, 2002). An important implication of ESDC is the role that 
different modalities such as bodily movements and cultural artefacts play in the understanding 
of science and mathematical concepts. 

We situate ESDC within a social constructivist framework that engages teachers’ prior 
knowledge in constructing new knowledge. Social constructivism focuses on the construction 
of knowledge as opposed to knowledge transfer typical of traditional teacher development 
programmes (Rout & Behera, 2014:11). Constructivism mirrors how learning takes place in 
the classroom environment. Koohang et al. (2009) assert that learning is enhanced when the 
teacher and learner roles are subsumed in the learning process. Social constructivism allows 
fluidity between these roles in the learning environment. 

For Vygotsky (1978), social constructivism is at its best when teachers reach the “zone 
of proximal development” (ZPD) where the knowledge of the entire group is collectively 
increased. This learning process requires a range of learning tasks beyond the knowledge 
level of any individual group member. Mastery of the task requires that all learners are 
engaged in the process. 

This framework provides a sound basis for context-specific professional development that 
is responsive to culture and relevant to teacher needs. We employ a contextualised approach 
to professional development that engages knowledge and the cultural assets of the local 
community, acknowledging that schools in rural areas are not entities separated from the 
cultural community. 

2.2  Nature of indigenous knowledge and nature of science, and the 
conundrum facing us in science education

Several researchers have shown that many South African teachers do not hold nuanced 
understandings of the nature of science (Cronje, 2015; Pretorius, 2015). Abd-El-Khalick, Bell 
and Lederman (1998), who developed an instrument to capture teachers’ views of the nature 
of science, make it clear that a relationship exists between teachers’ views of concepts, and 
how they teach. The argument is that, if teachers have good understandings of the empirical 
and inferential nature of science, it might be reflected in how they create learning opportunities 
(e.g., favouring inquiry learning over transmission-mode approaches). Ramnarain and 
Schuster (2014) show that there are many systemic issues that influence such transfer in the 

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classroom. The latter authors have shown that teachers (especially in rural schools) often 
“teach-to-the-test”, despite their own pedagogical orientations, due to pressure from, among 
others, parents and principals to achieve good examination results. 

Cronje (2015) developed an instrument to capture views on indigenous knowledge, based 
on the instrument developed by Abd-El-Khalick for views on the nature of science. She has 
shown that indigenous knowledge shares several tenets with the natural sciences, e.g., both 
are empirical, tentative, inferential and creative. There are, however, also differences, e.g., 
indigenous knowledge has a metaphysical character, unlike science. It is these metaphysical 
and holistic doctrines that create a conundrum regarding the inclusion of indigenous 
knowledge into the science and mathematics classroom. Taylor and Cameron (2016) show 
that there are three epistemological perspectives on such border-crossing: (a) indigenous 
knowledge is part of science; (b) indigenous knowledge and science are different domains of 
knowledge, and border-crossing is not advisable; and (c) indigenous knowledge and science 
should be seen as intersecting domains, and the focus in the classroom should be on the 
“shared space” between the domains. This complexity and uncertainty raise another concern: 
are teacher educators equipped to provide teachers (in-service training) and student-teachers 
(pre-service teacher education) with a good understanding of this complexity? This is the gap 
that this paper explores. How could a collaboration with the holders of indigenous knowledge 
and museums, as a “third partner”, address this concern?

3. METHODOLOGY
3.1 The short-learning programme
The Namaqua district covers an area of 126,836 square kilometres and includes six 
municipalities, namely the Richtersveld, Nama Khoi, Kamiesberg, Hantam, Karoo Hoogland 
and Khai-Ma. This research focused on the Hantam region that is bounded geographically 
by the Hantam Mountains, with the town Calvinia forming the hub of the region. It contains 
flora, fauna, indigenous knowledge and culture specific to this geographical region. Of specific 
interest, is that a sizable proportion of the people in this area are of Khoi-San (Nama, Griqua 
and !Xam) ancestry (De Beer, 2012). Adhering to the design-based research principles 
described by Anderson and Shattuck (2012), research requires long-term engagement and 
intensive collaboration in the research context to improve short-learning programmes (SLPs). 
The first cycle of the design-based research started with an SLP in the Hantam district in 2017.

The first SLP set out to build teacher capacity to facilitate epistemological border-crossing 
between indigenous knowledge and science curriculum topics. In the SLP, the focus was 
on problem-based learning, e.g., teachers engaged in an adapted Kirby-Bauer technique 
(Mitchell & Cater, 2000) to test anti-microbial activity of medicinal plants as well as cooperative 
learning, e.g., methods such as De Bono’s thinking hats. 

Cycle 2 of the design-based research began seven months later with a community-based 
qualitative inquiry exploring indigenous knowledge resources and the educational needs of 
the sector. The community inquiry and intervention follow-up ran concurrently. 

3.2 Research design
This research was designed to investigate a professional development SLP for science, 
technology and mathematics (STEM) teachers in the Hantam area in the Northern Cape. 
The Hantam professional development course is an example of professional development 

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that considers the social, cultural and historical context of rural education. According to 
Stake (2005), a case study is distinguishable by its unit of study in a bounded system. Yin 
(2014) adds that a case study is an empirical inquiry investigating a phenomenon in its real-
life context. This research proceeded as a qualitative case study because the boundaries 
between phenomenon and context were blurred (Yin, 2014). The aim in Cycle 2 was to see 
how inputs from indigenous knowledge holders could further enhance the impact of the SLP. 

3.3 Data sampling
3.3.1 Population 
The target population included community members and teachers in the Hantam district. 
A total of seventy-seven (77) teachers and eight (8) community members voluntarily 
participated in this research study. Of the teachers who participated in the SLP, thirty-seven 
(37) science teachers and forty (40) mathematics teachers volunteered. Community member 
participants included indigenous knowledge holders, the museum curator and officials from 
the Department of Basic Education. Most notable of the community member participants, 
were the local holders of indigenous knowledge. 

3.3.2 Sampling techniques
A snowball sampling method was used to invite Hantam residents to participate in the second 
cycle of research. Semi-structured interview conversations were conducted with eight (8) 
community members (notably the holders of indigenous knowledge), museum staff (the 
Calvinia Museum) and officials from the Department of Education. During Cycle 1, STEM 
teachers in the Namaqua District were invited to participate in an SLP held in the town of 
Calvinia. The criteria for inclusion were that participants were STEM teachers who had the 
desire and ability to travel to Calvinia to participate in a professional development course. 
These criteria were met by all participating teachers in the SLP. At the conclusion of the course, 
attending teachers were asked to voluntarily participate in the study. Those who volunteered 
were a random sample of the SLP participants. Purposeful random sampling lends credibility 
to the sample as Palinkas et al. (2015: 534) suggests. 

Purposive sampling was used to select community member participants. Patton (2002) 
recommends purposive sampling in qualitative research to render information-rich cases. The 
purposive strategy was employed with snowball sampling to recruit a homogeneous population 
of community members. Snowball sampling is based on the connectivity of the community, 
as volunteers suggest other possible volunteers who have similar characteristics (Huberman, 
1994:90). In this regard, we were interested in indigenous knowledge holders in the Hantam 
region. We relied on familial and network connections of the community “gatekeeper” as a 
strategy to collect a homogeneous sample of knowledge holders. 

This combination of strategies was deemed most effective for our research design and 
the best use of our limited resources. The sample size in this study was chosen to ensure 
data saturation, in order to distil design principles for contextualised teacher professional 
development (Yin, 2003). While this case is not intended to generalise to all contexts, we 
do expect the findings to generalise to the “underlying” context of the study (Onwuegbuzie, 
2003:400), namely teacher professional development in the rural context within South Africa. 

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3.4 Data collection 
This research proceeded in two phases. The first phase was the SLP conducted in the Hantam 
region. The second phase involved community-based inquiry. This phase occurred eight (8) 
months later in the Hantam community. Each phase is explained in detail below.

Phase 1
A total of seventy-seven (77) teachers attended the intervention – thirty-seven (37) science 
teachers and forty (40) mathematics teachers. Teachers voluntarily completed one-on-one 
interviews during the two-day intervention. After the intervention, they were granted six months 
in which to complete portfolios documenting the application of professional development skills 
and indigenous knowledge integration into their classroom instruction. Data obtained from 
teacher interviews and professional development portfolios assisted facilitators to distil new 
design principles to better serve the educational needs of teachers in the rural Hantam context. 

Phase 2
A total of eight (8) community members consented to voluntarily participate in the research. All 
eight participants were residents of the Hantam community. One participant was a museum 
curator, three were indigenous knowledge holders (one employed by the museum) and four 
were community residents. All participants volunteered to participate in an audio-recorded 
biographical interview guided by a semi-structured questionnaire. Two participants completed 
a video narrative explaining indigenous knowledge and Hantam culture. 

The semi-structured biographical interview protocol comprised seven (7) questions. The 
semi-structure was selected to allow participants to narratively reflect on their residence in 
the Hantam community and the culture of the place. This structure also allowed participants 
to engage in storytelling, which is a mode of cultural transmission in indigenous knowledge 
systems. The first three questions were biographical in nature, specifically asking participants 
about the length of their residence in the Hantam area. One question asked whether the 
participant’s family had generational residence in the area. The remaining questions were 
topical to explore aspects of daily life and cultural values that community members hold 
dear. Participants could choose to skip questions they experienced as uncomfortable. The 
biographical interview was audio recorded. 

The video narrative was purposed to capture visual images and representations of science 
in their daily lives. Participants were issued cameras and asked to take pictures of aspects of 
nature and the environment that represent science and citizenship. In a subsequent meeting, 
participants were asked to explain the significance of the images. 

3.5 Data analysis
Data included researcher observations and field notes, oral interviews and video narratives. 
Interviews and narratives were transcribed and coded along with researcher notes. 
Descriptive codes were used according to Saldana’s (2009) technique. Themes emerged 
from the process of coding and categorising the data. Codes were grouped into categories 
and themes emerged from comparison of categories with the research question. This paper 
reports preliminary findings of the ongoing design-based research.

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Speight Vaughn & De Beer Contextualising science and mathematics 

3.6 Ethical considerations
Ethical clearance was obtained from the university (NWU-00271-16-A2 for Cycle 1; NWU-
HS-2017-0135 for Cycle 2) and community gatekeepers. Two participants volunteered to 
record video narratives explaining indigenous knowledge and Hantam culture. Permission for 
teacher participation in the study was sought in writing from the Department of Basic Education 
in the Namakwa District. Permission for involvement of Khoi-San indigenous knowledge 
holders was obtained from community gatekeepers. We were also guided in this research 
by the San Code of Research Ethics (2017), the first indigenous code of researcher ethics 
in Africa. All volunteers were requested to complete an informed consent form that explained 
the research aims and objectives and volunteers’ right to withdraw from the study at any time. 
The consent included an explanation of risks and benefits associated with participation in the 
study. Volunteers completed an interview. Privacy and confidentiality were observed by the 
use of pseudonyms and firewall data protection. 

4. FINDINGS
Themes emerging from the data show that education in the Hantam rural environment is 
embedded in the social and cultural fabric of the area. Education is connected to indigenous 
knowledge, cultural artefacts and issues of social justice. Professional development initiatives 
would do well to consider the cultural context of rural schools to better meet the needs of 
teachers in these environments. This paper reports preliminary findings of ongoing research. 

4.1  Theme 1: Social connectedness of education and contextualised 
STEM education 

Participants indicated that education in the rural environment is not an isolated institution. 
Memci, the Calvinia Museum Curator, stated that she often collaborates with teachers and 
students to provide resources and needed support for teachers: 

Every year, foundation phase learners come to the museum to do their history project. I 
take them on a tour of the museum and show them the resources we have here. I work with 
the teachers to organize the learners to come every year. 

Memci nurtured the educational connection between community and schools by providing 
cultural and historical artefacts to assist learners in constructing history projects. In the 
Hantam rural context, sustainable professional development should utilise already existing 
community connections.

Education in the Hantam is everyone’s business. Gammie, the local traffic policeman, 
utilises the school to connect students with cultural knowledge through the rieldans. The 
rieldans is a form of Khoi-San cultural knowledge that promotes cultural identity and community 
engagement (Van Wyk, 2013). Gammie boasts: 

The rieldans is the property of the Khoisan people. It is their knowledge and identity. The 
rieldans is important because people of Khoisan roots are losing their identity from Western 
influence.

Gammie’s dance troops are students in local schools that come from farms. His work 
maintains the connection between farms and schools in the Hantam. Gammie explained how 
he uses the rieldans to encourage educational achievement: 

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I tell them they can do anything. They can use what they learn on the farm in school. The 
rieldans is knowledge of the farm and they can be proud of what they know from the farm.

The need for contextualised teacher professional development prompted the teacher 
educators in this project to focus on the affordances of traditional music for learning in the 
mathematics classroom. Owing to generous funding obtained from the Fuchs Foundation, 
teachers and school learners were provided with “boom whackers”, plastic pipes of various 
lengths, that can be used as music instruments. These boom whackers were accompanied 
by sheet music, in which learners are taught about fractions (Figure 1). Boom whackers 
are coloured plastic tubes that work in the same way as xylophones. Music symbols were 
transposed to mathematical symbols (fractions, e.g., ¹⁄6, ⅛, etc.) with the size of the fraction 
indicating the time duration of the “hit” (Van der Walt & Potgieter, 2019). 

Figure 1: Teaching fractions in the mathematics classroom as inspired by indigenous music 

Additionally, Khoi-San indigenous knowledge and culture is embedded in the Hantam 
local culture. Education is not separate from social and economic issues affecting Hantam 
residents. Christien, an indigenous knowledge holder staying on a farm in the Agter-Hantam, 
stated: “I wish I could have been a teacher so I can teach the children about my plants and 
medicines. It is important for them to know what plants can do.”

Christien’s desire to pass on or transmit knowledge to future generations is a tenet 
of indigenous knowledge. She also recognised the importance of Khoi-San indigenous 
knowledge to science education in Hantam classrooms as she referenced medicinal properties 
of plants. In the Hantam many people rely on plants for medicinal purposes (De Beer, 2012). 
Christien also recognised the connection between education and economic issues in the farm 
community: “My son has the knowledge. He wanted to be a teacher but we work on the farm. 
We don’t have money to send him to varsity.”

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Speight Vaughn & De Beer Contextualising science and mathematics 

Christien’s dream of transmitting indigenous knowledge to teachers and students can 
be realised through the local museum. The museum curator agreed to house the memorial 
garden of Khoi-San medicinal plants, indigenous to the Hantam. The museum will also house 
a permanent exhibit of Khoi-San indigenous knowledge and influence in the Hantam area. 
These exhibits are an outgrowth of the cultural research we embarked on to contextualise the 
professional learning intervention. 

In the second half of 2017, we embarked on a teacher professional development 
programme for Life Sciences teachers in which insights about the importance of ethnobotany 
in this region resulted in tailor-made activities. De Beer and Van Wyk (2011) conceptualised the 
so-called Matrix Method for engaging in ethnobotanical surveys in the classroom. Teachers’ 
learning was scaffolded in this regard and they were introduced to ethnobotanical activities 
that learners can engage with in the Life Sciences classroom, such as an adapted Kirby-Bauer 
technique (Mitchell & Cater, 2000) to test whether medicinal plants that are culturally used, 
have any antimicrobial activity, as well as doing ethnobotanical surveys in the community. One 
of the teachers, Marlize, indicated that this resulted in much enthusiasm among her learners 
and the attainment of affective outcomes. One of the teachers started a project where her 
learners engaged in making herbarium voucher specimens for a class herbarium (Figure 2).

  

Figure 2: Resources that were provided to schools (herbarium presses and autoclaves) on 
the left-hand side, and a learner’s project in ethnobotany on the right-hand side 

The involvement of a holder of indigenous knowledge such as Christien, through her 
involvement in the museum, is able to provide a teaching and learning resource that could 
lead to more contextualised science education. 

4.2  Theme 2: The affordances of indigenous knowledge in STEM 
education for building self esteem 

Community participants indicated that they were alienated from educational institutions in 
the past. However, educational opportunities are available for adults since 1994. For Gertjie, 
education was connected to social justice. He was unfairly denied education in his youth 
because he lived on a farm: “I had to work on the farm. When I could go to school, the farmer 
said I had hair on my face, I need to work on the farm.”

When educational opportunities were made available, Gertjie was denied the privilege of 
going to school because “he had hair on his face” (referring to the fact that, as an adolescent, 
he had a beard); otherwise stated he was too old and more useful as a farm worker than as a 
learner in school. In adulthood, Gertjie realised education as his human right through literacy 
programmes. He can now learn to read and write. In his words: “No one has to read for me, I 
can read myself.”

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Education is embedded in community life, but local indigenous knowledge is not common 
in school classrooms. Carin, a Foundation Phase administrator, asserted:

Khoi-San indigenous knowledge and stories should be in the curriculum to build 
confidence in the learners. Most of them (learners in her school) are Khoi-San. They 
have the knowledge at home and in their communities, but it has to stay at home when 
they come to school.

Integrating communities in schools holds innumerable benefits for building children’s self-
esteem. Older participants stated that indigenous knowledge was confined to the realm of the 
home. It was not valid in schools. Carin explained that Khoi-San indigenous knowledge is the 
way that she knows in the veld. She grew up hearing Khoi-San stories about the veld. She 
learned about the environment and atmosphere from those stories. She regards indigenous 
knowledge as essential for building the self-esteem of children. However, this knowledge is 
not included in the curriculum.

The intimate connection between education, community and indigenous knowledge in the 
Hantam is best illustrated by a vignette from Marlize’s ethnobotanical survey. One of her 
Grade 10 learners, Henrico, was so inspired by this assignment that he visited the Calvinia 
library and he asked the librarian for books on the flora of the Hantam. He was given a 
dissertation on the ethnobotany of the Hantam (De Beer, 2012), and while working through 
the text, he stumbled upon a photograph of his uncle, Martiens. The latter was consulted 
during this ethnobotanical survey in 2012. Henrico was so inspired by this “knowledge in the 
blood”, that he decided that he would like to pursue a career in botany after passing Grade 12. 
The acknowledgement of his own cultural knowledge did much to build his self-esteem and a 
sense of pride in his rich Khoi-San heritage. 

5. DISCUSSION AND CONCLUSION
Nelson Mandela (2005:vi) stated “the most profound challenges to South Africa’s development 
and democracy can be found in its rural hinterlands”. Rural environments are typically areas 
of high concentrations of poverty, unemployment and low educational attainment (Myende, 
2014). 

The historically present depravation of South Africa’s rural areas makes quality 
education not only an imperative but also an issue of social justice and citizenship (Odora-
Hoppers, 2004). Teacher professional development in the rural Hantam environment was 
contextualised by building on existing community partnerships and integrating Khoi-San 
indigenous knowledge into STEM classrooms. This community-based approach informed 
the design of teacher professional development aligned with the educational needs of the 
community. Embodied, distributed and situated cognition provided a foundation to explore the 
interaction between physical and social environment that is active in indigenous knowledge 
contexts. The use of embodied ways of knowing decolonises ways of knowing and practising 
science and mathematics in STEM classrooms. The embodied perspective also provided a 
lens through which to explore the affordances of cultural assets in contextualising teacher 
professional development. The contextualised teacher professional development approach 
presented in this paper strengthened partnerships between the community and schools 
aimed at improving teacher competencies and making science and mathematics instruction 
relevant to the learners. Contextualised teacher professional development has the potential to 

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Speight Vaughn & De Beer Contextualising science and mathematics 

harness knowledge assets and cultural resources present in rural communities, making social 
transformation a possibility. 

6. ACKNOWLEDGEMENT
The authors acknowledge funding from the National Research Foundation and the Fuchs 
Foundation. Views expressed are not necessarily those of the NRF or Fuchs Foundation.

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