{"id":125167,"date":"2012-08-22T10:10:34","date_gmt":"2012-08-22T13:10:34","guid":{"rendered":"http:\/\/revistapesquisa.fapesp.br\/?p=125167"},"modified":"2015-11-27T13:20:43","modified_gmt":"2015-11-27T15:20:43","slug":"the-brazilian-galapagos","status":"publish","type":"post","link":"https:\/\/revistapesquisa.fapesp.br\/en\/the-brazilian-galapagos\/","title":{"rendered":"The Brazilian Galapagos"},"content":{"rendered":"
\"Life<\/a>

Life in the sands of northern Bahia state, with and without feet (from left to right): Tropidurus amathites<\/em> from Santo In\u00e1cio; Nothobachia ablephara<\/em> and Calyptommatus leiolepis<\/em> from Alagoado; Tropidurus pinima<\/em> from Santo In\u00e1cio<\/p><\/div>\n

Thirty-two years after his first expedition to the sand dunes of the S\u00e3o Francisco River, biologist Miguel Trefaut Urbano Rodrigues, from the University of S\u00e3o Paulo (USP), is still surprised at \u201cthat crazy fauna,\u201d as he puts it. In 1980, when he was 27 and even thinner than he is today, he traveled under a merciless sun throughout Santo In\u00e1cio, a city then made up of 200 inhabitants in northern Bahia state, and was astonished by the diversity of similar animals: the sister species had only small differences in appearance or genetic make-up. The nearly identical creatures lived in the sand dunes on either side of the river. They had differentiated from a common ancestor and followed their own evolutionary paths from the time that the river \u2013 which at that particular point is only 200-300 meters wide \u2013 came to separate them.<\/p>\n

From the very first trip he brought back a new species of lizard, today called Eurolophosaurus amathites, which lives only there. On other expeditions, he and his team found animals that had never been described, like a two-headed snake and a subterranean snake, both with sister species from the other side of the river. In the dunes of the Brazilian Sahara, an area that measures 7,000 km2 and stretches along 120 km of river, the team already identified nearly 30 species and eight new exclusive genera of lizard (exclusive to the area), which is more than in all the deserts of North America or Africa. There, and only there, lives a rodent that measures 20 cm, the rabo-de-facho (spiny rat), as well as a bacurau (nightjar) that measures 20 cm high, similarly adapted to the sand dunes of the S\u00e3o Francisco. These dunes display a biological diversity that is comparable to the Galapagos archipelago, on whose fauna Darwin based his development of the theory of human evolution.<\/p>\n

In recent years, Rodrigues and his team of 20 researchers have been explaining the genetic and evolutionary mechanisms that guided the differentiation of lizards measuring no more than 5 cm in length. The oldest species of the same taxonomic genus of lizards still look like lizards; they have short bodies and, shall we say, normal limbs. The species that began to form over the last thousand years or so, however, started losing digits. Their limbs shrank or disappeared, and their bodies became elongated, to the point where some species of lizards look like snakes except for the small appendages that would have been the front feet of their distant ancestors.<\/p>\n

The biologists believed that the loss of complex structures like the limbs was irreversible \u2013 it is the so-called law of irreversibility of evolution, or Dollo\u2019s Law, in honor of Belgian naturalist Louis Dollo, who presented the theory in 1890. However, one of the lines of lizards with smaller limbs showed that it is possible to get the limbs back. In collaboration with Rodrigues, Tiana Kohlsdorf, along with her team from USP Ribeir\u00e3o Preto, studied 15 species of lizards of the genus Bachia that live throughout South America. The oldest among them had limbs with five toes and the more recent had four, then three, then two \u2013 and then three again. \u201cThere is a reversal, since the genetic information was not lost, but rather, it evolved again, because the toes that reappeared are not exactly the same, \u201c says Kohlsdorf.<\/p>\n

She, along with Rodrigues and colleagues from Yale University, presented these conclusions in the journal Evolution in 2006. They received so much criticism that they had to publish a counterargument in 2010, in an article that also appeared in Evolution, as a way to settle the debate. \u201cBased on the tools of statistical analysis we developed,\u201d Kohlsdorf says, \u201cgroups from other countries began to show reversion of wings in insects and other animals.\u201d<\/p>\n

While the debate raged on, the USP biologists confirmed that in at least two genera of lizards exclusive to the sand dunes, Calyptommatus and Nothobachia, the loss of limbs is irreversible. The animals had only miniscule appendages of what the limbs had been and were similar in appearance to snakes. Kohlsdorf admits, \u201cWe don\u2019t know why only the Bachias were able to reverse the loss of limbs.\u201d<\/p>\n

\"094-097_trefaut_esp50\"<\/a>Juliana Rossito, a researcher in Rodrigues\u2019 group, examined embryos and adults of the genus Calyptommatus at various stages of development to understand how the loss of limbs might have occurred. She observed that in the embryo, the femur begins to form between the fifth and sixteenth days, but then it disappears. Her analyses indicate that this genus of lizards is ready to be born in one month \u2013 and not six, as in the case of the closest species \u2013 perhaps as a result of the effects of temperature or the scarcity of water. Rodrigues adds, \u201cThis species found a way to accelerate its development through natural selection.\u201d<\/p>\n

According to Rodrigues, the reduction in the number of feet and the elongation of the body may have occurred during the evolutionary history of lizards of the family Gymnophtalmidae, made up of 45 genera, including Bachia and Calyptommatus, as a result of adaptations that allowed them to avoid extreme temperatures. This process gave way to species that were able to bury themselves in order to escape predators, as well as the cold and heat, which can reach 50\u00b0C in the sand. It is estimated that this process must have occurred at least two dozen times throughout the history of these lizards. This in turn advanced the origin of unique and at times even repugnant lizards as well as a group of animals with its own habits, famous in its own right \u2013 the snakes.<\/p>\n

In order to understand how and why the lizards are becoming able to live buried in tunnels or caves, Agust\u00edn Camacho filmed and analyzed hundreds of tests that compared the locomotion, the ability to escape and the feeding habits of 12 species of lizards of the family Gymnophtalmidae using cameras placed in sand inside the laboratory. \u201cThe elongated body and absence of feet seem to favor the development of the fossorial lizards that are able to escape predators more quickly, feed more and bury themselves more easily than those with feet,\u201d he concluded. \u201cBut it\u2019s still not possible to say which morphotype is better adapted to life in the sand, because even the species with four feet is abundant. They survive well and are seen by the dozens in the sand dunes.\u201d According to him, desert lizards of Australia lived a similar evolutionary life.<\/p>\n

Camacho represents the second generation of biologists on the trail of strange creatures in the sands of northern Bahia state. He studied biology in Andalusia, Spain, but \u201cwas passionate about coming to the tropics,\u201d he says. He traveled to S\u00e3o Paulo in 2002 for a short course on venomous animals and lizards, returned to Spain to finish his studies, and in late 2003 moved to Salvador, Bahia, to work on his master\u2019s degree at the Federal University of Bahia. His advisor, Pedro Rocha, had completed a doctoral degree on the ecology of the lizards in the S\u00e3o Francisco sand dunes, advised by none other than Rodrigues. In late 2007, Camacho moved to S\u00e3o Paulo and is now pursuing his doctoral degree in an office one floor above that of Miguel Rodrigues.<\/p>\n

Rodrigues maintains the same work methodology he had when he first began studying snakes and lizards 40 years ago. First he compares the external features such as the number and shape of the scales, the body length and eye shape. Then he identifies the new species and builds a phylogeny \u2013 the history of a species, beginning with the oldest. K\u00e1tia Pellegrino, a professor at the Federal University of S\u00e3o Paulo, uses another approach and began to study the blood relationship among lizards by comparing 10 genes. DNA analyses often indicate that the analyses obtained on the basis of external features need to be revised.<\/p>\n

Rodrigues and his work group are seeing how restricted environments are able to limit the development of new species with unique characteristics and habits. The creatures that live in the sand dunes are so specialized that they do not survive in \u2013 or even venture into \u2013 the neighboring caatinga. Animals that are typically found in the caatinga, in turn, only marginally venture into the sand dunes. Even among the animals themselves, specialization into different environments occurred. Some species of lizards live only on clusters of rocks and do not traverse the caatinga areas that separate the rocky outcrops.<\/p>\n

\"The

MIGUEL TREFAUT RODRIGUES\/ IB-USP<\/span>The Santo In\u00e1cio sand dunes: a unique space that shelters sister species with distinct evolutionary histories MIGUEL TREFAUT RODRIGUES\/ IB-USP<\/span><\/p><\/div>\n

From the other side of the Atlantic<\/strong>
\nRodrigues observed the same phenomenon \u2013 isolated populations of Platysaurus, lizards from another family, but who are very similar in appearance to those of one of the groups of Tropidurus, who also have flattened bodies and live only among the stones \u2013 in Mozambique, where he went for the first time in 2007. His plan is to go back there in 2013 to conduct a survey of lizards and snakes in the north and south of Mozambique in the company of other Brazilian and Mozambican biologists. They want to see if the genera of this lizard population in Africa originated at the same time as those in Northeastern Brazil. If so, biologists may be able to tell parallel stories of lands that were close together millions of years ago.<\/p>\n

Similar creatures can have very different stories, however. In 2008, by comparing DNA strands from 10 populations of lizards of the genus Eurolophosaurus, Jos\u00e9 Carlos Passoni, Maria L\u00facia Benozzati and Rodrigues, all from USP, showed that one of the species, the Eurolophosaurus divaricatus, a lizard that measures 25 cm in length and lives on the left bank of the S\u00e3o Francisco River, would have appeared 5.5 million years ago. The inhabitants of the opposite bank would have appeared more recently: the E. nanuzae 3.5 million years ago and the E. amathites at least 1.5 million years ago.<\/p>\n

Calculations of when these lizard species originated greatly exceed the modest 15,000 years previously concluded using geomorphological data. At that time, the river, as its topography changed, would have diverted its flow from the interior out to sea. The internal lagoons along whose banks the lizards sunned themselves may have disappeared or the river may have absorbed part of the left bank as it began to flow eastward rather than westward. According to Rodrigues, the separation between the northern and southern banks would occurred some 8 to 10 million years ago.<\/p>\n

Now it seems clear to him that rivers \u2013 and not just the S\u00e3o Francisco \u2013 work as geographical barriers to the development of new species of reptiles and amphibians. A few years ago, Pellegrino, Rodrigues and other biologists demonstrated the validity of this notion with a species of gecko from the Atlantic Forest, the Gymnodactylus darwinii. Populations of this species that are found to the north and south of the Doce River, which drains areas in the states of Minas Gerais and Esp\u00edrito Santo, were once thought to be closely related. They no longer appear to be so; one has 38 chromosomes and the other has 40.<\/p>\n

Frenchman Antoine Fouquet, who did his post-doctoral studies with Rodrigues, concluded that the forests of Guyana served as an important biological sanctuary for the differentiation of fauna from the Amazon region over the last few thousand years. Interestingly, the first species of snake that Rodrigues identified in 1978, when studying biology in Paris (he completed his undergraduate degree abroad and graduate work in Brazil), came from the Guianas. He identified his first Brazilian species in 1980. How many, in total, has he identified? \u201dI\u2019ve never stopped to count,\u201d he quips, between modesty and impatience with having to do the calculation. In 2010, Peter Uetz of the J. Craig Venter Institute in the U.S. did have the patience and actually did the calculation. The result: in an article published in the journal Zootaxa about the world\u2019s top 40 most productive biologists in terms of reptile species discovery since the 18th century, Rodrigues, the only Brazilian to make the list, is in 35th place, having described 53 species. Today, that number exceeds 60.<\/p>\n

Miguel Trefaut Rodrigues has contracted malaria, dengue fever and many other illnesses from hiking through the forest undergrowth, often at night, in pursuit of the creatures that make him happy. Some of the rigors of travel as well as the intellectual output of this group may be seen on the lab\u2019s website: www.ib.usp.br\/trefaut<\/a>. Rodrigues knows that he has accomplished a significant amount, but he is also concerned about what remains to be done and what may have been lost already. \u201cWe don\u2019t know anything. I\u2019m becoming more and more aware of how completely ignorant we are,\u201d he says. \u201cThere are sister species of lizards in the Andes and sandbanks of the Atlantic Forest. What happened to the rest of them? They disappeared!\u201d<\/p>\n

Projects
\n1<\/strong>. Studies on the ecology and differentiation of the reptile fauna of the mid-S\u00e3o Francisco River sand dunes (Lepidosauromorpha, squamata<\/em>) (n\u00ba 1996\/03554-0<\/a>) (1997-2002);\u00a0Grant mechanism\u00a0<\/strong>Thematic project;\u00a0Coordinator\u00a0<\/strong>Miguel Trefaut Urbano Rodrigues \u2013 Butantan Institute\/USP;\u00a0Investment\u00a0<\/strong>R$ 388,398.04
\n2<\/strong>. System and evolution of the neotropical herpetofauna (n\u00ba 2003\/10335-8<\/a>)\u00a0(2004-2011);\u00a0Grant mechanism\u00a0<\/strong>Thematic project; Coordinator\u00a0<\/strong>Miguel Trefaut Urbano Rodrigues \u2013 Butantan Institute\/USP;\u00a0Investment\u00a0\u00a0<\/strong>R$ 975,589.35
\n3<\/strong>. Comparative phylogeography, phylogenesis, paleoclimate modeling and taxonomy of neotropical reptiles and amphibians (n\u00ba 2011\/50146-6<\/a>) (2012-2016);\u00a0Grant mechanism\u00a0<\/strong>Thematic project; Coordinator <\/strong>Miguel Trefaut Urbano Rodrigues \u2013 Butantan Institute\/USP; Investment\u00a0<\/strong>R$ 1,747,802.04<\/p>\n

Scientific articles
\n<\/em>KOHLSDORF T. and WAGNER G. P. Evidence for the reversibility of digit loss: a phylogenetic study of limb evolution in Bachia (Gymnophthalmidae: Squamata)<\/a>. Evolution<\/strong>. v. 60, n. 9, p. 1896-912, 2006.
\nFOUQUET, A. et al<\/em>. Molecular phylogeny and morphometric analyses reveal deep divergence between Amazonia and Atlantic Forest species of Dendrophryniscus<\/a>. Molecular Phylogenetics and Evolution.<\/strong> v. 62, p. 826-38, 2012.
\nAMARO, R. C. et al<\/em>. Demographic processes in the montane Atlantic rainforest: Molecular and cytogenetic evidence from the endemic frog Proceratophrysboiei<\/a>. Molecular Phylogenetics and Evolution<\/strong>. v. 62, p. 880-88, 2012.<\/p>\n

From our archives
\n<\/strong>In the midst of snakes and lizards<\/a> –<\/em>\u00a0Issue 169 \u2013 March 2010
\nAt the feet of dinosaurs<\/a> –<\/em>\u00a0Issue 154 \u2013 December 2008
\nA treasure on the banks of the S\u00e3o Francisco River<\/a> –<\/em>\u00a0Issue 57 \u2013 September 2000<\/p>\n","protected":false},"excerpt":{"rendered":"Lizards from S\u00e3o Francisco River express their own evolutionary histories","protected":false},"author":17,"featured_media":0,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"_exactmetrics_skip_tracking":false,"_exactmetrics_sitenote_active":false,"_exactmetrics_sitenote_note":"","_exactmetrics_sitenote_category":0,"footnotes":""},"categories":[1237],"tags":[231],"coauthors":[5968],"class_list":["post-125167","post","type-post","status-publish","format-standard","hentry","category-biology-special-2","tag-evolution"],"acf":[],"_links":{"self":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/125167","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/users\/17"}],"replies":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/comments?post=125167"}],"version-history":[{"count":0,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/125167\/revisions"}],"wp:attachment":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/media?parent=125167"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/categories?post=125167"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/tags?post=125167"},{"taxonomy":"author","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/coauthors?post=125167"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}