The Chipaya of Bolivia: Dermatoglyphics and ethnic relationships

Dermatoglyphic data on 15 traits (digital arches, digital radial loops, digital ulnar loops, digital whorls, I loops, I_r loops, H loops, ? loops, III loops, IV loops, mainline C absence, total ridge count, a-b ridge count, atd angle, and mainline index) are presented for 141 Chipaya Indians of Bolivia. Ethnic relationships of these Indians to nine South American Indian tribes (Alacaluf, Atacameño, Aymara, Cashinahua, Chácobo, Chama, Chané, Quechua, and Sirionó) are explored by means of a genetic distance analysis using 21 alleles. Genetic distances are complemented with linguistic and geographic distances between the Chipaya and the other tribes. Genetic distances were found not to be significantly correlated with linguistic and geographic distances. Combining the information available, it is concluded that the Chipaya are most likely ethnically related to the Arawak speakers of the tropical forest.     

Distribution of hereditary blood groups among Indians in South America. II. In Peru

Blood specimens were procured from the following putatively pure Indians of the Peruvian rain forest: 90 Piro and 89 Campa on the Urubamba and Tambo rivers, 142 Shipibo and 14 Isconahua on the Rio Ucayali near Yarinacocha, 151 Aguaruna at Santa Maria de Nieva, where the Marañon and Nieva rivers join, and from 122 Ticuna and 9 Yagua near the Brazilian border on the Amazon. Specimens from highland Indians were obtained from 93 Aymará and 181 Quechua at Puno and environs. These 891 specimens were tested for antigens in the A-B-O, M-N-S-s, P, Rh-Hr, Lutheran, K-k, Lewis, Duffy, Kidd, and Diego (Di^a) systems, and for the Wright (Wr^a) aglutinogen. Serum samples from these bloods were tested for haptoglobins and transferrins and hemolysates were prepared and examined for hemoglobin types. Results for these tests with claculated gene frequencies are presented, for the most part, on appropriate tables. A map is included to show the locations of the populations from which blood samples were procured. As in South American Indians generally, frequencies are high for the O gene it being the only gene of the ABO system which appears in isolated jungle populations and the Aymará. Gene frequencies are usually high also for M, s, R¹ (CDe), R² (cDE), Lu^b, k, Le^H, and Fy^a; and low or absent for A, B, N, S, Mi^a, Vw, R^o (cDe), r (cde), Lu^a, K, Le¹, Fy^b, and Wr^a. The Diego (Di^a) gene is present but varies greatly in frequencies among tribes. Hp¹ gene frequencies vary from 0.44 to 0.69 among the Peruvian Indians tested. Transferrin CD was encountered in only one population i.e., in 3 of 86 Piro (gene frequency Tf^D= 0.02). All others were C. All Peruvian Indian bloods tested electrophoretically contained only hemoglobin (A) as a major component.     

Distribution of hereditary blood groups among Indians in South America. V. In northern Brazil

This paper reports the results of tests made for hereditary antigens in blood samples procured from Indians in northern Brazil. Specimens were procured from 423 putatively full-blood persons of the following tribes: in the province of Roraima from 261 Macuxi, 48 Uaica, 27 Xirixano, 10 Uapixana, 9 Cacarapai and 9 Paramiteri; in Pará from 21 Assurini; and in Amapá from 38 Galibi. Erythrocyte samples were tested for factors in the A-B-O, M-N-S-s, P, Rh-Hr, Lutheran, Kell-Cellano, Lewis, Duffy, Kidd and Diego systems. Serum samples were tested for haptoglobins and transferrins. Hemolysates, prepared from whole blood, were tested for hemoglobin types. The results are presented on appropriate tables as number and per cent of phenotypes for the various blood group anigens and their calculated gene frequencies. Locations from which blood samples were procured are listed in the tables and shown on a map (fig. 1). All the 423 samples except one Macuxi belonged to group O. The Uaica tribe had a low frequency for M (0.534). All others showed the high frequency usually observed in Amerinds. The s allele was high in all except the Galibi in which the frequency was (0.500). Frequencies for P² was higher than for P¹ in all except the Assurini and Galibi, theirs was high for P¹ (1.00) and low for P² (0.00). The frequencies for R¹ (CDe) and R² (cDE) were high and all others in the Rh-Hr system were low or absent. All specimens were positive for Cellano (k) and negative for Kell (K). There was a complete absence of Lewis (Le₁), excepting in the Uaica and Xirixano in which populations Fy^a allele frequencies were higher than 0.500. The distribution of the Jk (a+) phenotype and corresponding ellele frequencies varied widely in Brazilian Indians as did those for Diego (a+). The haptoglobin Hp¹ allele frequencies were in essential agreement with those reported elsewhere for Indians in South America, and all transferrins determined were classified as Tf C. All samples tested for homoglobin types contained homoglobin (A) as a major component, but five members of the Galibi tribe possessed hemoglobin (S) as well.     

Distribution of hereditary factors in the blood of Indians of the Gila River, Arizona

This paper reports the distribution of blood groups, A-B-H secretors, haptoglobins, transferrins and hemoglobin types among Indians of the Gila River Valley in Arizona. Specimens were procured from the following putative full-bloods: 909 Pima, 37 Papago, and 124 Maricopa; and from the following known mixed-bloods: Pima-Papago 134, Pima-Maricopa 26, Pima-Other Indian 41, Pima-Caucasian 33. These 1304 samples were tested for factors in the A-B-O, M-N-S-s, P, Rh-Hr, Lutheran, Kell-Cellano, Lewis, Duffy, Kidd and Diego blood group systems, and for additional blood factors (Wr^a), Do^a, Vel, Yt^a, Co^a, Gy^a, Sav, and L. W. Serum samples were tested for haptoglobins and transferrins. Hemolysates, prepared from whole blood, were tested for hemoglobin types. The results are presented on appropriate tables as number and per cent of phenotypes for the various blood group antigens and their calculated allele frequencies. Locations of the populations from which blood samples were procured are shown on a map (fig. 1). Tests made by earlier workers on the blood of Arizona Indians and related tribes are presented for comparison and discussed. The usual high frequencies for allele O reported in Amerinds was found among the putatively full-blood Gila Indians; the 124 Maricopa presented the maximum frequency of 1.000. High frequencies were reported generally for M, s, P¹, R¹ (CDe), R² (cDE), k (100%) Fy, and Do^a alleles. Low frequencies were reported for N, S, r (cde), R° (cDe), fy, Le¹w and Di^a (Pima only). There was a wide variation in frequencies for jk, and Hp¹, and there were 17 Transferrin Tf B₁C observed in 270 Pima samples tested. All the remaining were classified as Tf C except two Tf B;C from mixed-bloods. All samples tested for Vel, Yt^a, Co^a, Sav, and Hemoglobin (A) showed the maximum frequency (1.000) for their genes. The following antigens were completely absent: Lu^a, Mi^a, Vw, Mt^a, p, P^k, r^y (CdE), K, and Wr^a. The results of this study suggests that the Papago tribe presents fewer genes of non-Indian origin than the Pima, and the Maricopa least of the three populations.     

Distribution of hereditary blood groups among Indians in South America. IV. In Chile with inferences concerning genetic connections between Polynesia and America

This is the fourth paper in a series on the distribution of blood groups among Indians of South America. It reports the findings on the Indians of Chile and the Polynesians of Chile's Easter Island. Blood specimens were procured from the following putatively pure Indians and unmixed Polynesians: 44 Alacaluf of Puerto Eden, Isla Wellington, 141 Mapuche (Araucanian) of Lonquimay, Malleco Province, 80 Atacameños of Antofagasta Province, and 45 Polynesians of Easter Island. These 310 samples were tested for blood factors in the A-B-O, M-N-S-s, P, Rh-Hr, Lutheran, K-k, Lewis, Duffy, Kidd and Diego systems, and for the Wright (Wr^a) agglutinogen. Serum samples were tested for haptoglobins and transferrins. Hemolysates prepared from the blood clots were tested for hemoglobin types. The results are presented as phenotype incidences and calculated gene frequencies in appropriate tables. Locations of the populations from which blood samples were procured are shown on two maps. The high frequencies for the O gene usually reported for South American Indians obtain in putatively pure Chilean Indians but A¹ is high in Easter Island Polynesians. In both Indians and Polynesians M, s, R¹ (CDe), R² (cDE), Lu^b, k, Le^H, and Fy^a gene frequencies are high and B, N, S, Mi^a, Vw, Rº (cDe), r (cde), Lu^a, K, Le¹, Fy^b, and Wr^a (Ca) are low or absent. The Diego (Di) gene is present in the Mapuche and Atacameños but absent in the Alacaluf and Polynesians. Hp¹ gene frequencies were determined only in the Alacaluf and Atacameños, in which they are 0.48 and 0.67 respectively. Transferrins were determined for the Alacaluf and Atacameños Indians and all were classified as Tf C. All Chilean Indian and Polynesian specimens were tested electrophoretically for hemoglobin types and all contained only hemoglobin (A) as a major component.     

Traditional knowledge hiding in plain sight – twenty-first century ethnobotany of the Chácobo in Beni,Bolivia

Background

The Chácobo are a Panoan speaking tribe of about 1000 members (300+ adults) in Beni, Bolivia. Originally nomadic, the Chácabo were relocated to their current main location in the 1960s. Researchers have visited the Chácabo since 1911. A first more detailed anthropological report exists from the late 1960s, and ecological–ethnobotanical studies were conducted in the 1980s and 1990s. The presented work represents a complete ethnobotanical inventory of the entire adult Chácobo population, with interviews and plant collection conducted directly by Chácobo counterparts.

Methods

Based on previous reports and our preliminary studies, we hypothesized that twenty-first century Chácobo plant use centered on income generation, and that traditional plant use related to household utensils, medicine and traditional crop varieties had almost disappeared. To test this hypothesis, we started the “Chácobo Ethnobotany Project,” training 10 indigenous Chácobo participants in ethnobotanical interview and plant collection techniques, in order to more fully document Chácobo knowledge and avoid the influence of foreign interviewers.

Results

Our study found 331 useful plant species in 241genera of 95 plant families, with leaves, roots and bark being the most commonly used plant parts The comprehensive documentation that these methods enabled completely nullified our initial hypothesis of knowledge loss. Traditional crop varieties are still widely grown and traditional knowledge is alive. Moreover, it is being actively recuperated in certain domains by the younger generation. Most Chácobo know, and can name, traditional utensils and tools, although only the older generation has still the skills to manufacture them. While many Chácobo still know the names and uses of medicinal species, the younger generation is however often unsure how to identify them.

Conclusions

In this paper we illustrate the complexity of perspectives on knowledge at different ages, and the persistence of knowledge over almost a century. We found that traditional knowledge was only partially affected by the processes of exposure to a market economy, and that different knowledge domains experienced different trends as a result of these changes. Overall knowledge was widely distributed, and we did not observe a directional knowledge loss.We stress the importance to not directly conclude processes of knowledge loss, cultural erosion or acculturation when comparing the knowledge of different age groups.

     

Distribution of hereditary blood groups among indians in South America. VII. In Argentina

This seventh and last paper in a series on the distribution of blood groups among Indians in South America reports the findings among Amerinds in Argentina. Blood specimens were procured from putative full-bloods of the following tribes: 38 Diaguita (Calchaqui), 230 Mataco, 90 Chiriguano, 142 Choroti, 51 Toba, 120 Chané, 96 Chulupi (Ashluslay), and 178 Araucano (Mapuche). These 945 samples were tested for blood factors in the A-B-O, M-N-S-s, P, Rh-Hr, K-k, Lewis, Duffy, Kidd, and Diego systems. Serum samples were tested for haptoglobins and transferrins. Hemolysates prepared from whole blood were tested for hemoglobin types. The results are presented in tables as phenotype distribution and calculated allele frequencies. Locations of the populations from which blood samples were procured are shown on a map of North and Central Argentina. High frequencies are reported for the O allele. Allele frequencies are high also for M, s, R¹ (CDe), R² (cDE), k, Le^H and Fy. They are usually low or absent for alleles B, N, S, Mi^a, Vw, R^o (cDe), r (cde), K, Le¹, and fy. The Di allele ranged from 0.013 in the Araucano (Mapuche) to 0.192 in the Toba. Allele frequencies aberrant for Indians were observed more often in the Araucano (Mapuche) and Diaguita tribes, due probably to greater inflow of non-Indian genes into their gene pool and perhaps also to genetic drift in small inbred populations. Hp¹ allele frequencies varied from 0.43 in the Choroti to 0.80 in the Diaguita. All samples tested for transferrins except six contained the variant Tf C; the six were B₁ C present in samples from one Mataco and six Araucano persons. All the specimens tested electrophoretically for hemoglobin types contained only (A) as a major component.     

Genetic studies in Paraguay: blood group, red cell, and serum genetic patterns of the Guayaki and Ayore Indians, Mennonite settlers, and seven other Indian tribes of the Paraguayan Chaco

Genetic studies of 540 Paraguayan Indians from nine tribal groups and 51 Mennonites are presented for ABO, MNSs, P₁, Rh, Kell, Lewis, Duffy, Diego; for serum immunoglobulins and haptoglobins, G6PD-deficiency, and thalassemia trait. Group O gene frequencies for all Indian groups were 1.00; for r (cde), 0.00. Tapiete, Lengua, Toba, and Sanapana R_z (CDE) frequencies were among the highest ever reported. N frequencies were high for Ache Kwera (Guayaki), Lengua, Cheroti, Guarayu, Tapiete; N and s low for Ayore. MS frequencies were high for Sanapana, Lengua, Ayore; Ns for Tapiete. Diego was notably absent for Toba, Lengua, Guarayu, Tapiete, Ayore. Homogeneous frequencies for Fy^a (1.000) occurred among Guarayu and Tapiete, and for P₁ among Guayaki. Inv(a) frequencies were low for Cheroti, Chulupi, Guayaki. Hp 1 among Guayaki (Ache Kwera 0.15) is lowest ever reported. G6PD deficiency and abnormal hemoglobins were uniformly absent from all groups. Mennonite results were homogeneous and point toward Dutch origins. Differences among groups studied, and between Paraguayan and other Amerinds emphasize importance of genetic drift and founder principle. Abandonment of their tribes by mixed-blood offspring is partly responsible for apparent genetic purity and homogeneity of groups.     

Research Methods Leading to a Perception of Knowledge Loss—One Century of Plant Use Documentation Among the Chácobo in Bolivia

The loss of traditional knowledge, concomitant with changes in livelihoods, languages, and demographics of indigenous and local groups, is a global concern. However, documenting such loss poses serious methodological challenges. Comparing the results of contemporary studies with past research is often problematic due to methodological differences. Here, comparing studies that attempted to document the traditional ethnobotanical knowledge of the Chácobo of Bolivia, we tried to examine whether knowledge loss was really occurring across more than 100 years or was only researcher’s perception. The Chácobo are a Panoan-speaking tribe of about 1000 members, first visited by researchers in 1911, and subsequently in the 1950s, 1960s, 1970s, 1980s, and 1990s. Each study had different foci, but all recorded ethnobotanical data. The first more detailed anthropological report exists from the late 1960s, and ecological-ethnobotanical studies were conducted in the 1980s and 1990s. Based on available literature, in particular the botanical studies of Boom (1987) and Bergeron (1998), it seemed that Chácobo plant use now centers on income generation. Both Boom (1987) and Bergeron (1998) perceived that traditional plant use related to household artifacts and medicine, as well as traditional crop varieties had almost disappeared. Here, we hypothesized that plant knowledge documented and the perception of so-called knowledge loss observed in these depended completely on the background of the interviewers and the methods employed, and that in a sufficiently comprehensive ethnobotanical study, we would be able to document all species and uses mentioned in previous studies. We tested this hypothesis by conducting a complete ethnobotanical inventory of almost the entire adult Chácobo population, with interviews and plant collection conducted directly by Chácobo counterparts. The results verify our initial hypothesis and showed that the loss of knowledge perceived in previous studies simply was an artifact of the research methods employed. Traditional crop varieties are still widely grown, most Chácobo know, and can name, traditional artifacts, and many still know the names and uses of medicinal species. However, some knowledge, including the manufacture of artifacts and proficient identification of many medicinal plants, is limited to the older generation.     

Distribution of blood groups among indians in South America. VI. In Paraguay

This paper on the distribution of hereditary factors in the blood of Indians in South America, reports the results of tests made on samples procured from Paraguayan Indians. Specimens from putatively full-blood persons were obtained from the following tribes: 88 Chamacoco, 36 Moro, 85 Chulupi, 207 Lengua, 100 Toba, 20 Yam Lengua, and 51 Guayaki, These 587 Samples were tested for factors in the A-B-O, M-N-S-s, P. Rh-Hr, Lutheran, Kell-Cellano, Lewis, Duffy, Kidd, and Diego systems. Serum samples were tested for haptoglobins and transferrins. He molysates, prepared from whole blood, were tested for hemoglobin types. The results are presented on appropriate tables as number and per cent of phenotypes for the various blood group antigens and their calculated allele frequencies. Locations of the populations from which blood samples were procured are listed on the tables and shown on a map (fig. 1). Of the 587 samples all except two Chamacoco belonged to group O. High frequencies are reported generally for M, s, P, R¹ (CDe), R² (cDE), k (100%) and Fy alleles in Paraguayn Indians. Low frequencies were generally reported for N, S, r (cde) and R° (cDe) alleles. There was a wide variation in frequencies for Di, Jk, and haptoglobin Hp¹. All tested for transferrins were classified as Tf C and all contained hemoglobin (A) as a major component. The following antigens were completely absent: Mi^a, Vw, p, P^k, r^y (CdE), K, and Le¹. Most notable is the unusual distribution of hereditary blood antigens among the Guayaki and Moro. The Guayaki had 100% P₁ and Fy^a; they were higher in R° (cDe), R¹ (CDe), and Jk^a; and lower in R² (cDE) and Hp¹ genes than other Indians; and Di was absent. The Guayaki differed from the other Indians also in having fair skin. The Moro were lower in the P¹ and Jk gene frequencies than is usually found in Amerinds, and the Di gene was absent. The Chamacoco also had an exceptionally low frequency for the P¹ gene (0.261).     

Distribution of hereditary blood groups among Indians in South America. I. In Ecuador

Blood specimens were procured from 658 Quechua, 36 Colorado, 233 Jivaro, 244 Cayapa, and 48 Secoya Indians of Ecuador. These were examined for antigens in the A-B-O, M-N-S-s, P, Rh-Hr, Lutheran, K-k, Lewis, Duffy and Kidd systems and for Diego (Di^a), Wright (Wr^a), and Berrens (Be^a) agglutinogens as well. Hemolystes were prepared and studied for hemoglobin types and the serum samples were tested for haptoglobins and transfserrins. Gene frequencies are high for O, M, s, R¹, (CDe), R² (cDE), Lu^b, k, Kp^b, Le^b and Fy^a; and low or absent for A, B, N, S, Mi^a, Vw, Mt^a, R⁰ (cDe), V (ce^s), Lu^a, K, Kp^a, Le^a, Fy^b, Js^a, Wr^a and Be^a. The Diego (Di^a) gene is present but its frequency varies greatly from tribe to tribe. Gene frequency Hp¹ is well within the range previously reported for Indians in Middle America excepting the Colorado in which population the frequency of 0.889 is unusually high. All 723 serum specimens tested for transferrins were C or CD. No D or BC types were found. All Ecuadorian Indian bloods tested electrophoretically contained only hemoglobin (A) as a major component.     

Intra and intertribal genetic variation within a linguistic group: The Ge-speaking Indians of Brazil

A total of 562 individuals living in four villages of two Brazilian Indian tribes (Cayapo and Krahó) was studied in relation to blood groups ABO, MNSs, P, Rh, Lewis, Duffy, Kidd and Diego; haptoglobin, Gc, acid phosphatase and phosphoglucomutase types. These results were compared with those obtained previously among the Xavante, and the inhabitants of three other Cayapo villages, all of whom speak Ge languages; the ranges in gene frequencies observed in a representative series of South American Indians from all over the continent were also compiled. The Ge Indians are characterized by low frequencies ofR^z, medium frequencies ofR¹,R², R⁰, orr,Jk^a andPGM¹₁, and high frequencies ofGc² andACP^A when compared with other South American tribes. Genetic distance analyses based on six loci indicate that the intratribal variability observed among Cayapo is of the same order of magnitude as those obtained among the Xavante and Krahó, being much less pronounced than those observed among the Yanomama and Makiritare. The intertribal differences within this linguistic group are much less pronounced than those encountered among tribes that speak more differentiated languages.     

The influence of cultural factors on the demography and pattern of gene flow from the Makiritare to the Yanomama Indians

A single village of Yanomama Indians was found to have frequencies of Di^a of 0.06 and of Ap^a of 0.08, in contrast to 40 other villages whereDi^a was absent and Ap^a quite rare. The source of these genes was identified as a village of Makiritare Indians, but the two allele frequencies were approximately the same or even higher in the Yanomama than in the Makiritare village. Demographic, social and cultural parameters affecting marriage and reproduction in the two tribes explain this. Genealogical relationships and informants' accounts collected in the field, when viewed against the traditional marriage practices, reproductive advantages of headmen, and differential treatment of captured women, indicate that the mating and reproduction parameters inherent in tribal social organization of this kind constitute an essential part of the explanation of the genetic findings. It is argued that mating systems of this sort are such that the probability of a new gene introduced by a captive surviving in the recipient population is a function of the sex of the initial carrier. The implications for tribalization and potentially radical changes in allele frequencies are briefly explored by considering aspects of settlement pattern and population fissioning known to characterize the tribes in question. Finally, it is shown that genetic sampling from a single location can and does result in unrepresentative allele frequencies when this single sample is taken to characterize the tribe as a whole.     

Multiple refugia and glacial expansions in the Tucumane–Bolivian Yungas: The phylogeography and potential distribution modeling of Calomys fecundus (Thomas, 1926) (Rodentia: Cricetidae)

The Yungas, a subtropical mountain rainforest of South America, has been little studied in relation to the evolutionary history of the large-bodied species of the genus Calomys. Particularly, two species have been synonymized: C. boliviae and C. fecundus; the first is only known from its type locality in the northern Bolivian Yungas, whereas the second is known along the Tucumane–Bolivian Yungas shared by Bolivia and Argentina. In this study, we combined a phylogeographic approach with ecological niche modeling, with samples covering most of the geographic range of C. fecundus. One mitochondrial and two nuclear genes were used for population genetic analyses. Current and paleoclimatic models were obtained. Nuclear genes resulted uninformative by retention of ancestral polymorphism with other species of Calomys. The mitochondrial marker revealed a complex network showing signals of several population expansions. Three genetic clusters in a latitudinal sense were detected, which are coincident with the three stable climatic zones estimated by current and paleoclimatic models. We determined a pattern of expansion during glacial cycles and ancestral refugia during interglacial cycles. None of the potential distribution models predicted the presence of C. fecundus in the type locality of C. boliviae. Therefore, we recommend making integrative taxonomic studies in the Bolivian Yungas, to determine whether or not C. fecundus and C. boliviae correspond to the same species.     

The distribution of transferrin and hemoglobin types in families of Suffolk and Targhee sheep1

Transferrin and hemoglobin types were determined for 2133 sheep (Suffolks, Targhees, and Suffolk × Targhee crossbreds) and gene frequencies were calculated. Analysis of ratios of hemoglobin types revealed a significant excess of lambs of hemoglobin B/B type in some matings. For transferrins, there was a deficiency of homozygotes for Tf^B in offspring of matings of Tf^B heterozygotes inter se.     

Gc and transferrin isoelectrofocusing subtypes among Brazilian Indians

A total of 397 persons living in six villages of three Brazilian Indian tribes were studied in relation to the Gc subtypes. The corresponding gene frequencies are more similar between the Gorotire and Caingang than between the Gorotire and the Krahó, despite the considerable geographical distance that separates the villages of these two first tribes and their lignuistic differentiation. An uncommon variant pattern (1C7) was observed in eight Gorotire Indians; it had been described for the first time in a Tibetan sample, furnishing additional evidence on the Asiatic origin of these Indians. The distinct Gc subtype frequencies observed in our main ethnic groups provide an important new tool for anthropological analyses. Tf subtypes were studied among the Caingang only. The frequencies of Tf^C1 and Tf^C2 are similar to those obtained by other researchers in Hessen, Germany.     

Unraveling the decolourizing ability of yeast isolates from dye-polluted and virgin environments: an ecological and taxonomical overview

Microcosm assays with dye-amended culture media under a shot-feeding strategy allowed us to obtain 100 yeast isolates from the wastewater outfall channel of a dyeing textile factory in Tucumán (Argentina). Meanwhile, 63 yeast isolates were obtained from Phoebe porphyria (Laurel del monte) samples collected from Las Yungas rainforest (Tucumán), via a classical isolation scheme. Isolated yeasts, both from dye-polluted and virgin environments, were compared for their textile dye decolourization ability when cultured on solid and liquid media. Nine isolates from wastewater and 17 from Las Yungas showed the highest decolourization potential on agar plates containing six different reactive dyes, either alone or as a mixture. Five yeasts from each environment were further selected on the basis of their high dye removal rate in Vilmafix^® Red 7B-HE- or Vilmafix^® Blue RR-BB-amended liquid cultures. Yeasts from wastewater showed slightly higher decolourization percentages after 36 h of culture than yeasts from Las Yungas (98?C100% vs. 91?C95%, respectively). However, isolates from Las Yungas exhibited higher specific decolourization rates than isolates from effluents (1.8?C3.0 vs. 0.9?C1.3 mg g^?1h^?1, respectively). All selected isolates were first grouped according to microsatellite-PCR analysis and representative isolates from each group were subsequently identified based on the 26S rRNA gene sequence analysis. Yeasts from wastewater were identified as the ascomycetous Pichia kudriavzevii (100%) and closely related to Candida sorbophila (99.8%), whilst yeasts from Las Yungas were identified as the basidiomycetous Trichosporon akiyoshidainum and Trichosporon multisporum. It is suggested that findings concerning yeast selection during screening programs for dye-decolourizing yeasts may be explained in the light of the copiotroph-oligotroph microorganisms rationale.     

Salivary peroxidase,Pm, and Ph protein polymorphisms in Malaysians

Summary Three human saliva genetic markers, namely, salivary peroxidase (SAPX), Pm, and Ph proteins, were investigated in the three major ethnic groups of Malaysia: Malays, Chinese, and Indians.For Pm, the allelic frequencies of Pm ⁺ for Malays, Chinese, and Indians are 0.385±0.030, 0.282±0.026, and 0.289±0.026 respectively. For Ph, the allelic frequencies of Ph ⁺ are 0.082±0.016 for Malays, 0.109±0.017 for Chinese, and 0.062±0.013 for Indians. For SAPX, the allelic frequencies of SAPX ¹ in Malays, Chinese, and Indians are 0.762±0.027, 0.755±0.027, and 0.723±0.026 respectively.     

The bifunctional role of LiuE from <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis>, displays additionally HIHG-CoA lyase enzymatic activity

Pseudomonas aeruginosa is able to utilize leucine/isovalerate and acyclic terpenes as sole carbon sources. Key enzymes which play an important role in these catabolic pathways are 3-hydroxy-3-methylglutaryl-coenzyme A (CoA) lyase (EC 4.1.3.4; HMG-CoA lyase) and the 3-hydroxy-3-isohexenylglutaryl-CoA lyase (EC 4.1.2.26; HIHG-CoA lyase), respectively. HMG-CoA lyase is encoded by the liuE gene while the gene for HIHG-CoA lyase remains unidentified. A mutant in the liuE gene was unable to utilize both leucine/isovalerate and acyclic terpenes indicates an involvement of liuE in both catabolic pathways (Chávez-Avilés et al. 2009, FEMS Microbiol Lett 296:117–123). The LiuE protein was purified as a His-tagged recombinant protein and in addition to show HMG-CoA lyase activity (Chávez-Avilés et al. 2009, FEMS Microbiol Lett 296:117–123), also displays HIHG-CoA lyase activity, indicating a bifunctional role in both the leucine/isovalerate and acyclic terpenes catabolic pathways.