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Introduction
“..… (I) have done what I could to encourage and expedite the work of others on these taxa, although it is frustrating, in a way, to leave so many of them unresolved.”
(Sydney Anderson 1997, Mammals of Bolivia).
Despite his sentiment on leaving matters unresolved, there is little doubt that Sydney Anderson left a legacy that will not only endure, but grow, as the biodiversity infrastructure he helped build is used by generations of scientists to come.
Over a decade of fieldwork (1984-1993), the Mammalian Diversity in Bolivia (MDB) survey established a highly productive model for integrated specimen-based field expeditions. With funding from the National Science Foundation and under the leadership of Sydney Anderson (American Museum of Natural History, AMNH), Terry Yates and Joseph Cook (Museum of Southwestern Biology, University of New Mexico, MSB), and Scott Gardner (University of California-Davis, UCD and the Manter Laboratory of Parasitology, University of Nebraska, Lincoln, HWWL), this highly collaborative project involved a number of Bolivian institutions including the Colección Boliviana de Fauna in the La Paz (CBF), the Museo de Historia Natural “Noel Kempff Mercado” in Santa Cruz, Bolivia (MHNNKM), Centro Nacional de Enfermedades Tropicales (CENETROP), Zoofauna SudAmericana-Santa Cruz, Instituto Boliviano de Biología de la Altura, La Paz (IBBA), and Instituto de Ecología, Universidad Mayor de San Andrés (UMSA). The MDB represented the initiation of a more rigorous, comprehensive, and integrated methodology in specimen preparation, designed to encompass not just the mammal and its morphologic characters, but to also archive as broad a spectrum of tissues as possible, and with a dual focus on each mammal specimen’s associated parasites. The traditional voucher (skin and skeleton-- Hafner et al. 1984, or fluid preserved specimen) was supplemented by an array of ultra-frozen tissues, chromosome cell suspensions, fecal samples, and endo and ectoparasites. Now termed the “Holistic Specimen” (Cook et al. 2016; Galbreath et al. 2019), but also known as the “Extended Specimen” (Webster 2017), these specimens provide a breadth of materials to address not only traditional systematic and taxonomic questions, but now facilitate and integrate questions in environmental change (e. g., climate change, habitat conversion, pollutants and toxicants, biodiversity loss, introduction of exotics), and other novel and evolving contemporary research areas (e. g., pathogen emergence and discovery, genomics, microbiomes, isotopic and molecular ecology, metagenomics, transcriptomics, and proteomics; Cook et al. 2017; Dunnum et al. 2017; Greiman et al. 2018; Schindel and Cook 2018).
The MDB project produced more than 10,000 holistic mammal specimens from diverse biomes throughout "el Corazón de Sudamérica". These materials are now deposited in the collections of the AMNH, CBF, MHNNKM, and MSB, along with thousands of lots of associated ectoparasites (e. g., fleas, ticks, lice) and endoparasites (e. g., helminths) that were deposited in the HWML. To date, those specimens and their related data have served as the basis for hundreds of publications and graduate theses. Many of those studies, in turn, have been highly cited, revealing how holistic mammalian surveys, if properly archived, can continue to produce diverse, integrated, novel perspectives on mammalian biology in this hyper-diverse region long after the initial field research is completed.
Collections serve as primary infrastructure for environmental science. Research questions using specimens today are often quite different from the original goals of specimen collection (McLean et al. 2016). The kinds of studies using samples and data from specimens have exploded (Pauli et al. 2017; Schmitt et al. 2018), yet sample availability for nearly all natural populations and species remains too limited (Malaney and Cook 2018). Sydney Anderson realized that building collections, essentially libraries of biodiversity, was key to ensuring their primary role in biodiversity sciences. Biodiversity sciences leverage this primary infrastructure in diverse ways. Herein, we point to how the integrated, holistic datasets uniquely offered by the Bolivian specimens have already improved understanding of geographic variation (e. g., morphological, genomic, ecological), interactions among organisms (e. g., host-parasite, host-microbiome, habitat), and the relationship between humans and wildlife health and will continue to do so well into the future. Multiple fields and scientific approaches can use this primary infrastructure and associated datasets to build and test hypotheses about natural and anthropogenically altered phenomena.
In addition to building scientific collections, the MDB survey combined with Sydney Anderson’s engagement with Bolivian national, regional, and university-based museums provided exceptional cross-cultural opportunities for both Bolivian and North American students (the next generation of specimen-based scientists) to gain hands on experience in field mammalogy, parasitology, and museum curation.
Here, we assess the extended impact of that decade long series of holistic surveys of mammalian diversity as a productive model for building enduring and highly integrated infrastructure for biodiversity and human health. We point to specific examples of impact, but more generally make a case for Sydney Anderson’s prescient view that collections, over time, become ever more powerful and essential scientific tools for understanding mammalian diversity and our rapidly changing planet.
Materials and methods
To assess the number of specimens held in collections and their availability for spatial analyses, we queried the Global Biodiversity Information Facility (GBIF) using the following parameters: Basis of record - “preserved specimen”; Country or area - “Bolivia”; Scientific name - “Mammalia”. During the MDB survey, AMNH did not have frozen tissue storage facilities so all tissue samples and karyotypes were deposited at the MSB. Tissues from traditional voucher specimens (skin/skeleton/fluid specimens) held at the AMNH were cataloged as tissue only specimens at MSB and linked to the corresponding vouchers cataloged at AMNH though the Arctos collection management database (arctosdb.org). In GBIF this results in duplicate records for the same individual so for these analyses we removed duplicates. For those GBIF records without coordinate information, we georeferenced those with unambiguous localities using GeoLocate (http:// www.museum.tulane.edu/geolocate/; Rios and Bart 2014).
To identify publications which utilized MDB specimens or data, we used Google Scholar searches based on a series of keywords (e. g., Bolivia, mammal, MSB, AMNH, CBF, MNKM) and our knowledge of the material collected and loaned. This publication list was then used to accomplish two objectives: 1) assess the breadth of research for which MDB specimens contributed to, and 2) build a Google Scholar profile with citation indices to assess total impact.
Evaluation of the research content area was accomplished by assigning each publication to one of seven broad categories: 1) Systematics, taxonomy, and phylogeography, 2) New records/species distributions, 3) Taxon accounts in larger reference works, 4) Species compilations or keys, 5) Conservation and biogeography, 6) Parasite and pathogen biology and discovery, and 7) other areas.
Results and discussion
Impact on Bolivian natural history specimen growth. The beginnings of Bolivian mammalogical collections dates back to the early 1800’s and continued sporadically into the early 1960’s. Accurately accounting for all Bolivian specimens archived remains daunting due to incomplete digitization in the broad array of collections holding material, and was not attempted for this report. We estimate that no more than 5,000 specimens resulted from these early efforts documenting the country for the period 1818 through 1962. Tarifa (2014) and Anderson (1997) provide detailed overviews of the important events, people and institutions involved in the early years of Bolivian mammalogy. The ensuing decade (1960’s) saw major projects focused on disease investigations related to a Bolivian hemorrhagic fever outbreak in the Beni region. These surveys by the Middle American Research Unit (MARU) and U. S. Army Medical Research and Development Command (USAMRD) generated large collections (ca. 13,000 specimens) now archived at the USNM, FMNH, and AMNH. The AMNH/USAMRD project led by Richard Van Gelder was Sydney’s first foray into documenting Bolivian fauna and represents his first contributions to Bolivian mammalogy. Subsequently, from 1979-1983, Sydney (accompanied by his wife Justine) made various journeys to Bolivia to collect mammals (ca. 1,200 specimens) throughout the country. These trips would serve as the foundation for later expeditions with the CBF, MHNNKM, MSB, and HWWL (Anderson 1997). Over the course of the decade-long MDB survey about 10,000 new “holistic” specimens were preserved and added to museum collections (Table 1) and by the time he began work on “Mammals of Bolivia”, he had access to about 36,000 specimens.
Table 1 Summary of expeditions from the Mammalian Diversity of Bolivia (MDB) survey (1984-1993).
| Year | Locations (Department) | Approx. Specimens |
|---|---|---|
| 1984 | Oruro, Cochabamba, Beni, Santa Cruz | 1,200 |
| 1985 | Beni, Chuquisaca, La Paz, Santa Cruz | 1,500 |
| 1986 | Beni, Chuquisaca, La Paz, Oruro, Pando, Potosi, Tarija | 1,300 |
| 1987 | Santa Cruz | 250 |
| 1988 | Santa Cruz | 700 |
| 1990 | Chuquisaca, Santa Cruz | 1,000 |
| 1991 | Cochabamba, Santa Cruz, Tarija | 1,770 |
| 1992 | Beni, La Paz, Santa Cruz | 770 |
| 1993 | Beni, Cochabamba, La Paz | 1,300 |
GBIF searches (GBIF.org; 19 April 2020) resulted in 36,249 records from 41 collections (GBIF Occurrence Download https://doi.org/10.15468/dl.rppf79) but that total includes specimens shared between MSB/AMNH. After removing duplicate records, 32,590 digitized specimens were available for analyses. Based on information provided in Anderson (1997) and Dunnum et al. (2018), we recognize there are also specimen records not available through GBIF and thus not reflected in the total, including the holdings of the four Bolivian natural history collections. Dunnum et al. (2018) reported a total of about 14,000 specimens from those collections: Museo de Historia Natural “Alcide d’Orbigny” (MHNC-M; 166 specimens), Colección de Fauna Centro de Biodiversidad y Genética (CCBG; 265 specimens), MHNNKM (5,200 specimens), and CBF (8,211 specimens). Thus, we estimate the total number of Bolivian specimens to approach 50,000, based on the combined GBIF data, un-digitized specimens held in other collections that we are aware of, and growth in collections since publication of Dunnum et al. (2018). Therefore, we estimate that there are approximately 0.045 specimens per km2 collected in Bolivia (50,000/1.099 million km2). About a third of the specimen records (12,015 specimens) in GBIF are not georeferenced, including much of the early collections by the Smithsonian (USNM), British Museum (NHMUK), and AMNH.
We (JLM) were able to georeference an additional 8,265 of those specimens to bring the total number to 28,834. Thus, we produced specimen heat maps (Figure 1) which included ca. 89 % of the specimens in GBIF, however, when also considering the specimens not available in GBIF, these analyses represent only about 60 % of the total Bolivian collections. This reduction in specimens for spatial analyses, reinforces the point that full value of specimens is only realized when they are properly georeferenced, digitized, and made available on-line. Thus, while patterns seen in these maps are largely accurate based on our knowledge of the primary areas of collection in Bolivia, inclusion of the material held in the Bolivian natural history collections would certainly refine the precision of the spatial distribution of specimen coverage.
Figure 1 Heat maps of Bolivian specimens available on GBIF and containing georeferenced data: 1a) specimens collected prior to 1963. 1b) specimens collected between 1963-1983. 1c) specimens collected during the period of the Mammalian Diversity of Bolivia (MDB) survey (1984-1993). 1d) specimens collected from 1994 through the present. 1e) combined total specimens for all years with numeric value for each hexagon noted.
From a temporal sampling perspective, there exist almost no areas where there is adequate sampling through time (Figures 1a to 1d), material and data absolutely vital to robustly assessing any type of environmental change. The forty-year period until 1963 (Figure 1a) illustrates the overall relatively low numbers of specimens, collected primarily from the central and eastern portions of the country, with nearly half the country devoid of any sampling. The period from 1963-1983 (Figure 1b) exemplifies the impact of disease related projects in northern and western lowlands as well as bat surveys in La Paz and Santa Cruz departments. However, the southern highlands were largely unsampled during those twenty years. The decade of the MDB surveys (Figure 1c) saw a major increase in sampling across the country but most prominently along the eastern versant of the Andes. Despite only representing a single decade, the MDB survey era represents the period of greatest spatial coverage. Despite gains made during that period, based on these data there has been a reduction in sampling over the past 20 years (Figure 1d), a period of significant global climate change and environmental alternations. These numbers perhaps would not look quite as grim if specimens from the Bolivian natural history collections were included because many of those represent recently collected material but the general issue would remain.
Pooling all specimens through time (Figure 1e) shows that about 60 % of the country has < 100 specimens/hex (~10,000 km2), including areas in the southern highlands and the Bolivian Chaco which are extremely depauperate of material. About 90 % of the areas within the country are represented by fewer than 500 specimens. The only areas with numbers over 1,000 are around the major urban centers of La Paz (2,783 specimens), Cochabamba (1,226 specimens), and Santa Cruz (3,778 specimens), and the BHF outbreak investigation area (6,191 specimens) in the Beni.
The take-home message remains that, like the majority of places on our planet, Bolivia remains vastly under-sampled on both a spatial and temporal scale and there are many parts of the country which have already been irreparably altered through habitat conversion before they could be even partially documented. Large-scale funded projects like the MDB survey have the potential to make large contributions, but are unfortunately few and far between, thus broad spatial and temporal surveys of biodiversity need to be supported through diverse collaborations leveraging both in-country and global entities and resources.
Impact of Bolivian Specimen Infrastructure on Science. The MDB project developed new field-based protocols for preserving holistic specimens that would facilitate research that integrated across studies of hosts and parasites (Gardner 1996; Gardner and Jiménez-Ruiz 2009). These field techniques have been subsequently expanded and refined through other large sampling efforts worldwide with new cohorts of mammalogists and parasitologists (e. g., Beringian Coevolution Project, Cook et al. 2017). From those efforts, best practices in holistic sampling of mammal and parasite faunas (Galbreath et al. 2019) now codify the concept of the holistic mammal specimen. Having now advocated for the concept of the "holistic specimens", it must be said that Sydney Anderson was a proponent of saving any piece of animal material he encountered on the roadways of Bolivia, no matter how flattened or degraded as it might be. He would wryly note each “road-kill record" would add another “vouchered dot" on the distribution map for a particular species. More than a few specimens were composed of nothing more than a patch of skin scraped from the roadway, carefully annotated with location and date of collection. In retrospect, those materials were important as they often represented a larger, poorly sampled carnivore and are now irreplaceable because technology has advanced to the point of allowing the extraction of genetic or isotopic signatures from extremely marginal material.
Sydney Anderson’s years spent working in Bolivia and then reviewing the collections at MHNNKM, CBF, AMNH, or MSB produced many publications dealing with the distribution and systematics of this South American mammalian fauna (Anderson 1982, 1985, 1993, 1997; Anderson et al. 1982; Anderson and Olds 1989; Anderson et al. 1993; Anderson and Webster 1983; Anderson and Yates 2000; Anderson et al. 1987; Cook et al. 1990; Gardner and Anderson 2001; Glanz and Anderson 1990; Hinojosa et al. 1987; Olds and Anderson 1987, 1989; Olds et al. 1987; Salazar and Anderson 1990; Salazar et al. 1994). His monograph, “Mammals of Bolivia, Taxonomy and Distribution” (1997), has a place on every Neotropical mammalogist’s bookshelf and has served as a vital resource for diverse research, public health, and wildlife management initiatives for three decades (670 citations). A growing body of subsequent works have built upon that foundational contribution.
Notwithstanding Sydney Anderson’s published contributions to the systematics and taxonomy of Bolivia’s mammalian fauna, his true Bolivian legacy may lie in the vast series of natural history specimens and associated data that he collected, compiled, organized, and curated over the decade he spent on this project. He was a seasoned and enthusiastic field mammalogist, even when setting his own traplines was no longer possible. He could always be counted on to finish preparing and check the work on all specimens. During the days, he would fastidiously monitor the progress on the drying skins and carcasses, often checking for maggots or mold, and moving the skeleton pile into direct sunlight or out of the rain. His catalog numbered in the 10,000’s, and he took it upon himself to not only prepare massive numbers of specimens while in the field but to also carefully document the activities of the day and the localities visited (Figure 2). Much of what he recorded would eventually make it into various accounts on Bolivian fauna, including his book “Mammals of Bolivia”. The collections from the MDB survey also have fostered a wide array of research on mammals and associated parasites.
Figure 2 Syd Anderson writing fieldnotes and tending to drying specimens (Rio Aceromarca, La Paz Department, 1991).
A series of Google Scholar searches identified over 500 papers that used specimens or associated data from the MDB survey (Figure 3). It should be noted that only 49 of these papers were published during the life of the NSF grants, suggesting that the long-term value of specimen-based initiatives continue to generate value, as well as integrate knowledge across scientific fields, long after the grant cycle has concluded.
The suite of publications spanned most aspects of mammalian biology. As would be expected with specimen-based research, the majority of papers focused on mammalian systematics, taxonomy, or phylogeography. Specimens used in taxon accounts for larger reference works (e. g., Mammals of South America, Vol 2: Rodents (Patton et al. 2015) were the second largest area of use. New records, distributional extensions, and taxonomic lists and keys combined to made up about 10 % of the papers. Conservation oriented papers constituted about 4 % of the total, although many of the systematic, taxonomic and distributional papers also had a conservation emphasis. The utility of holistic specimens to bridge disciplines and contribute to integrated science is evidenced by the considerable number of papers which investigated mammalian parasite or pathogen biology (Figure 4). The integration and inclusion of both mammalogists and parasitologists on all MDB expeditions resulted in likely the largest collection of mammalian endoparasites from a Latin American fauna. To this day, these archived specimens continue to be a source of novel parasite discovery.
Figure 3 Publications by year utilizing specimens or data from the Mammalian Diversity of Bolivia survey.
The Google Scholar profile generated for the > 500 publications of the MDB survey (https://scholar.google.com/citations?user=860kCvYAAAAJ&hl=en&authuser=2) consists of over 20,000 citations (Figure 5a). The associated citation profile (total citations was 20,619, H-index = 68, i-10 index = 340; Figure 5b) undoubtedly has missed publications based on the MDB specimens, nonetheless, the profile demonstrates the enduring and increasing value of specimen-based holistic sampling of biodiversity (Cook et al. 2016; Schindel and Cook 2018), as recently summarized in the extended specimen concept (Lendemer et al. 2019). Far from being static specimens sitting idle in museum drawers or tissue samples slowly degrading in biorepository freezers, these materials provide a vital foundation for ever more diverse sets of investigations because our ability to probe these materials has increased due to technological advances (e. g., genomics, viromics, stable isotope chemistry, 3-D ctScans, etc.) that are generating an ever-increasing body of knowledge on South American mammals and their parasites. In addition, the steady increase in citations of these publications over the past three decades demonstrates both their centrality and enduring value as these irreplaceable materials are utilized for new questions and probed with new technologies (Figure 5b).
A further demonstration of the power of specimens to integrate across diverse areas of investigation in biology and extend science is a MSB specimen of Andalgalomys pearsoni (MSB:Mamm:55245) collected from Santa Cruz department in 1984 by Sydney Anderson, Dwight Moore, and Joseph Cook in the first year of this project. That specimen was subsequently designated as the holotype of A. p. dorbignyi by Olds et al. (1987). The initial two genetic sequences were generated and accessioned in GenBank for inclusion in phylogenetic analyses accompanying the description of the new genus TapecomysAnderson and Yates (2000) and a subsequent loan of material in 2002 to Scott Steppan’s lab at Florida State University provided the other five sequences available in GenBank. These seven sequences have now been heavily utilized by other researchers.
Table 2 New descriptions of mammals from the Mammalian Diversity in Bolivia survey.
| Species | Citation |
|---|---|
| Andalgalomys pearsoni dorbignyi | Olds, Anderson, and Yates, 1987 |
| Tapecomys primus | Anderson and Yates, 2000 |
| Thomasomys andersoni | Salazar-Bravo and Yates, 2007 |
| Ctenomys andersoni | Gardner, Salazar-Bravo, and Cook, 2014 |
| Ctenomys erikacuellarae | Gardner, Salazar-Bravo, and Cook, 2014 |
| Ctenomys lessai | Gardner, Salazar-Bravo, and Cook, 2014 |
| Ctenomys yatesi | Gardner, Salazar-Bravo, and Cook, 2014 |
| Akodon siberiae | Myers and Patton 1989 |
| Monodelphis sanctaerosae | Voss, Pine, and Solari 2012 |
Figure 5 a) Cumulative growth curve of citations generated by MBD survey publications. b) Citations by year from the MDB survey.
Sequences in GenBank that are tied to permanent museum specimen are considered a best practice (Federhen et al. 2009) because these sequences can be verified and extended (from a single locus to full genomes) as technology improves our ability to probe samples. A significant percentage of GenBank data (up to 25%) are incorrectly assigned to the wrong taxon (Longo et al. 2011) and cannot be re-examined as they are not tied to a permanent voucher. Direct links between GenBank and museum specimens have had major consequences for research in molecular genetics, genomics, and viromics by significantly expanding the accessibility of museum resources to a wider array of the scientific community. More than 50% of requests for tissue loans made to the Division of Genomic Resources at the Museum of Southwestern Biology now originate from investigators who have discovered this resource through GenBank. GenBank accessions in turn substantially solidify the role of specimens as primary infrastructure in biology. For example, data from specimens representing rare species are often used repeatedly as our knowledge of particular groups of organisms expands. A single specimen may voucher and integrate across many independent scientific studies. The impact of each specimen thus is amplified over time as the number of associated studies multiplies (Dunnum and Cook 2012). Thus since its deposition, this specimen of Andalgalomys pearsoni (MSB:Mamm:55245) has been part of the foundation of 32 publications (Figure 6).
Figure 6 Citations for publications utilizing individual specimen of Andalgalomys pearsoni (MSB:Mamm:55245).
Anderson (1985) reported 277 species for the country as of 1984. The most recent treatment of mammals of Bolivia includes 406 native species (Aguirre et al. 2019). This is an increase of 129 species since the initiation of the MDB survey. The large increase in the number of species registered for the country since 1984 (Figure 7) corresponds to a significant increase in specimen coverage, the breadth and quality of preserved material (including “holistic specimens” with ultra-frozen tissue), digital availability via the www, a cohort of young Latin American biologists, and new approaches in systematic research that provide more detailed views of geographic variation and species limits.
In addition to new distributional records from throughout the country, many descriptions of taxa new to science are based on the MDB collections, including nine mammals (Table 2) and at least 34 parasite taxa (Table 3).
Table 3 New descriptions of endo and ectoparasites from the Mammalian Diversity in Bolivia survey.
| Parasite | Host Species | Citation |
|---|---|---|
| Andrya boliviensis | Phyllotis osilae | Havercost and Gardner 2010a |
| Andrya vesicula | Phyllotis xanthopygus | Havercost and Gardner 2010a |
| Caroloxyuris boliviensis | Oxymycterus paramensis | Jimenez-Ruiz and Gardner 2003a |
| Cryptocotyle thapari | Lutra longicaudis | Gardner and Thew 2006 |
| Didelphoxyuris thylamisis | Thylamys venustus | Gardner and Hugot 1995 |
| Dipetalonema yatesi | Ateles chamek | Notarnicola et al. 2007 |
| Eimeria boliviensis | Hydrochoerus hydrochaeris | Casas et al. 1995 |
| Eimeria cochabambensis | Marmosops noctivagus | Heckscher et al. 1999 |
| Eimeria granifera | Ctenomys opimus | Lambert et al. 1988 |
| Eimeria ichiloensis | Hydrochoerus hydrochaeris | Casas et al. 1995 |
| Eimeria magnirostrumi | Uroderma magnirostrum | Duszynski et al. 1999 |
| Eimeria marmosopos | Marmosops ocellatus | Heckscher et al. 1999 |
| Eimeria micouri | Micoureus constantiae | Heckscher et al. 1999 |
| Eimeria montuosi | Ctenomys opimus | Lambert et al. 1988 |
| Eimeria opimi | Ctenomys opimus | Lambert et al. 1988 |
| Eimeria oruroensis | Ctenomys opimus | Lambert et al. 1988 |
| Eimeria trinidadensis | Hydrochoerus hydrochaeris | Casas et al. 1995 |
| Helminthoxys abrocomae | Abrocoma cinerea | Hugot and Gardner 2000 |
| Laelaps neacomydis | Neacomys spinosus | Gettinger and Gardner 2005 |
| Lauroia bolivari | Dasypus novemcinctus | Jimenez-Ruiz and Gardner 2003b |
| Lentiella lamothei | Proechimys simonsi | Haverkost and Gardner 2008 |
| Linstowia schmidti | Thylamys venustus | Gardner and Campbell 1992 |
| Litomosoides andersoni | Ctenomys opimus | Brant and Gardner 1997 |
| Litomosoides ctenomyo | Ctenomys opimus | Brant and Gardner 1997 |
| Molinema boliviensis | Holochilus brasiliensis | Notarnicola et al. 2012 |
| Monoecocestus andersoni | Graomys domorum | Haverkost and Gardner 2010a |
| Monoecocestus eljefe | Galea leucoblephara | Haverkost and Gardner 2010b |
| Monoecocestus microcephalus | Graomys domorum | Haverkost and Gardner 2010b |
| Monoecocestus petiso | Galea musteloides | Haverkost and Gardner 2010b |
| Monoecocestus poralus | Phyllotis caprinus | Haverkost and Gardner 2010b |
| Monoecocestus sininterus | Tapecomys wolffsohni | Haverkost and Gardner 2010b |
| Monoecocestus threlkeldi (redescription) | Holochilus brasiliensis | Haverkost and Gardner 2009 |
| Pritchardia boliviensis | Marmosops noctivagus, Marmosops ocellatus, Metachirus nudicaudatus | Gardner et al. 2013 |
| Yungasicola travassosi | Akodon mimus | Gardner and Perez-Ponce de Leon 2002 |
Type material, including symbiotype specimens (Frey et al. 1992) for these new taxa are held at the MSB and AMNH. In addition to the biodiversity infrastructure developed by the MDB survey, it also had a profound effect on the individuals who took part in it. The inclusion of Bolivian and American students in all aspects of the MDB surveys provided experience, inspiration, and opportunities which would have life-long implications in their scientific development.
Many of these students credit their career choices and subsequent success to experiences gained and relationships made during these expeditions. Over the course of these projects at least 75 students (13 grad students, > 50 Bolivian and 11 U.S. undergraduates) participated in field studies (Figures 8a, b) ranging from the Chaco of Tarija north to the Amazonian forests of the Pando, and from > 5000 m in the western Cordillera above the Altiplano eastward to < 500 m in the Chiquitano forests of eastern Santa Cruz. At least 29 of the students later received advanced degrees and many have now built successful careers in academia, natural history museums, or with conservation nongovernmental organizations (NGOs). The MDB survey, as well as concurrent and later USNM projects led by Louise Emmons, helped facilitate a surge in mammalogy in Bolivia and leading to a cohort of Bolivian biologists who took the torch and have now contributed massively to the understanding of the country’s fauna.
Sydney Anderson was accorded the title of “El Padre de la Mastozoología Boliviana Contemporánea” (Tarifa 2014) for his four decades of research on Bolivian mammals and collection infrastructure. Four Bolivian mammals (Oryzomys andersoniBrooks et al. 2004; Thomasomys andersoniSalazar-Bravo and Yates 2007; Oecomys sydandersoniCarleton et al. 2009; Ctenomys andersoniGardner et al. 2014) and one parasite (Litomosoides andersoniBrant and Gardner 1997) have now been named after Sydney Anderson. His name will certainly always be tied to the mammals of Bolivia but also to the generations of mammalogists he helped inspire and mentor along the way.
Figure 7 Accumulation of new species recorded for the country of Bolivia (modified from figure 1 in Aguirre, Tarifa et al. 2019).
Critically, museums now not only provide materials for biodiversity studies, but they also serve a primary informatics role providing the associated original collection data (i. e., locality, date, taxonomic identity, measurements) through on-line databases (e. g., Arctos), and also serve as the nexus for connecting the ever-growing sets of bigdata (e. g., accessions to GenBank, IsoBank, MorphoBank, etc.) that were derived from these carefully preserved materials (Hedrick et al. 2020). We can confidently predict that the value and use of the Bolivian mammal specimens that were archived in multiple institutions in Bolivia and the United States under Sydney Anderson’s leadership will continue to increase in the future as societal concerns related to environmental change (e. g., biological annihilation, climate change, emerging zoonotic pathogens) become more pressing, scientific questions evolve, and technology continues to develop. To this point, the current COVID-19 pandemic has highlighted our general unpreparedness to respond to emerging pathogens, fundamental ignorance of our planet's natural ecosystems, and the effects of our encroachment on them. Holistic collections are ideally positioned to play a fundamental role in a proactive response to future emerging disease scenarios (Cook et al. 2020), a role they can only play if grown in a manner championed by Sydney Anderson and colleagues.
Figure 8 a) Mammalian Diversity in Bolivia survey students processing holistic voucher specimens (1991). From left; Mariel Campbell, Leonardo Maffei Fagale, Erika Cuellar Soto, Jon Dunnum, Forrest Davis, Jorge Salazar-Bravo, Marcello Zalles. b) Part of MDB field crew. From left: Nella Sanchez Cook, Jose Carlos Herrera, Jim Woods, Marcello Zalles, Mariel Campbell, Jon Dunnum, Forest Davis, Joe Cook) in Serrania Siberia in 1991.
