Notes on the History and Adaptation of the Apache Tribes

Sometime between A.D. 1100 and 1600 a group of Athapaskan-speaking tribes migrated from northwestern North America into the southwestern United States, where most eventually came to be referred to as Apaches. Compared with the majority of Amerindian tribes, relatively little is known about this group, specially about their life prior to the arrival of Europeans in the seventeenth century. This paper is an attempt to gather together widely scattered information about their prehistoric movements, their economy, and their general style of adaptation to the Southwest.     

Reply to Opler on Apachean Subsistence, Residence, and Girls' Puberty Rites

Archaeological evidence shows that Apaches occupied the central Plains area from A.D. 1525–1725 in Wyoming, South Dakota. Nebraska, Kansas, and Colorado. Toward the end of this period they were semi-sedentary farmers living in houses generically like those of the Plains-Prairies earth lodge. Because in their southward migration they contacted Plains-Prairies farmers earlier than those in the Southwest proper, and farming was women-dominated and residence matrilocal for the Hidatsa, Mandan, Arikara, Pawnee, and Wichita, it seems highly probable that these Plains Apaches acquired matrilocal residence and a female farming division of labor at this time before contacting Tanoans in the Southwest. The more western Apacheans, who may not have had contact with Plains tribes, could have acquired matrilocal residence from western Pueblos, including the Keresans, who were probably all matrilocal before Spanish contact. It is doubtful that the wild plant gathering of Apachean women was sufficient to cause matrilocal residence, because in parts of California and the Great Basin where women gathered a greater proportion of the diet than Apachean women, residence was vary rarely matrilocal.     

The Identity of La Salle’S Pana Slave

Abstract

In June 1682 Robert Cavelier, Sieur de La Salle, was presented with a “Pana” boy by the Illinois Michigamea Indians. The boy told La Salle of his history as a captive in four Indian tribes. He described Indian village locations and listed the tribes which had “many” horses. The significance of the information for which he was the source depends on the tribal identity of the captive. It has been suggested in anthropological literature that “Pana” indicated “Pawnee,” Ponca, Arikara, Wichita, even Apache. After examination of evidence-linguistic, cultural, historical - it seems most likely he was a Southern Pawnee, a Wichita. If this was so, then his information substantiates the theory of Kroeber, Brant and others that some Kiowa Apaches were still living in the southern Plains in the late 17th century.     

Distribution of four founding mtDNA haplogroups among Native North Americans

The mtDNA of most Native Americans has been shown to cluster into four lineages, or haplogroups. This study provides data on the haplogroup affiliation of nearly 500 Native North Americans including members of many tribal groups not previously studied. Phenetic cluster analysis shows a fundamental difference among 1) Eskimos and northern Na-Dene groups, which are almost exclusively mtDNA haplogroup A, 2) tribes of the Southwest and adjacent regions, predominantly Hokan and Uto-Aztecan speakers, which lack haplogroup A but exhibit high frequencies of haplogroup B, 3) tribes of the Southwest and Mexico lacking only haplogroup D, and 4) a geographically heterogeneous group of tribes which exhibit varying frequencies of all four haplogroups. There is some correspondence between language group affiliations and the frequencies of the mtDNA haplogroups in certain tribes, while geographic proximity appears responsible for the genetic similarity among other tribes. Other instances of similarity among tribes suggest hypotheses for testing with more detailed studies. This study also provides a context for understanding the relationships between ancient and modern populations of Native Americans. © 1996 Wiley-Liss, Inc.     

Rates and Causes of End-Stage Renal Disease in Navajo Indians, 1971-1985

The rates of end-stage renal disease are much increased in American Indians, but no longitudinal study of its rates and causes has been undertaken in any tribe. This 15-year study of rates and causes of treated end-stage renal disease in the Navajo, the largest Indian tribe, supplies an important model on which to base projections and plan interventions. Treated end-stage renal disease in Navajos has increased to an age-adjusted incidence 4 times that in whites in the United States. Diabetic nephropathy accounted for 50% of all new cases in 1985, with an incidence 9.6 times that in US whites, and was due entirely to type II disease. Glomerulonephritis caused end-stage renal disease in Navajos at a rate at least 1.8 times that in US whites and afflicted a much younger population. The predominant form was mesangial proliferative glomerulonephritis associated with an immune complex deposition. Renal disease of unknown etiology, which probably includes much silent glomerulonephritis, accounted for 20% of all new cases. The aggregate Navajo population with end-stage renal disease was 9 years younger than its US counterpart.These observations reflect the genesis of the epidemic of diabetic nephropathy afflicting many tribes. Urgent measures are needed to contain this. In addition, the etiology and control of mesangiopathic, immune-complex glomerulonephritis of unusual severity, a previously unrecognized problem, need to be addressed.     

Genetic relationships between Amerindian populations of Argentina

A total of 495 individuals from five different Argentinian tribes was examined for variation in 23 blood group and protein genetic systems, and the results were integrated with previous data on some of these systems. These tribes generally present RH * R1, PGM1 * 1, and ACP * A frequencies lower and RH * R2, ESD * 1, and GLO * 1 prevalences higher than those observed in other South American Indian groups. Earlier studies with mitochondrial DNA showed that haplogroup A was present in low frequencies in these tribes, but haplogroup B showed a high prevalence among the Mataco. Average heterozygosities are very similar in the five tribes, while estimates of non-Indian ancestry are generally low. Both the blood group and protein, as well as the mtDNA data sets, divide the five tribes into two groups, and the relationships obtained with the blood group and protein systems are exactly those expected on the basis of geography and language. However, the topology obtained with the mtDNA results was different, possibly due to sampling effects or diverse patterns of exchange between the groups related to sex.     

Finger and palmar dermatoglyphics in Seminole Indians of Florida

Hand prints of 146 Florida Seminoles were obtained at the Brighton, Big Cypress and Dania reservations and at the Indian Agency in Dania. Comparisons with other tribes of North American Indians (Comanche, Arapahoe, Navaho, Hopi and Pueblo) reveal similarities with respect to fingerprint indices, frequencies of patterns in all palmar areas, and transverseness of palmar ridges. Comparisons of Seminoles and other North American tribes with the Mayans of southern Mexico and Guatamala show striking differences in pattern frequencies in the thenar/first interdigital area of the palm. Among North American Indians, the frequency varies from 18.49% among Seminoles to 28.5% among Navahoes, whereas all Mayan tribes which have been studied range between 40 and 50%. Pattern frequencies are higher in the thenar/first interdigital area than in the hypothenar area among all Amerindians who have been tested. This trend is the reverse of that found in other racial groups. North, Central and South American Indians are similar with respect to relatively high finger pattern indices, low frequencies of patterns in the hypothenar area, low frequencies of accessory triradii in the interdigital areas and moderately transverse palmar ridges.     

Sickle cell disease among tribes of Andhra Pradesh and Orissa,India

Sickle cell disease is observed to occur in significantly high frequencies amongst the tribes of India. It has surged to the fore as an important public health problem among tribal groups, which needs serious attention. This paper presents the distribution of this abnormal genetic problem among scheduled tribes of India, in general and among those of Andhra Pradesh and Orissa states, in detail. Though the prevalence of sickle cell trait is high, the sickle cell disease cases are found to be very low, since all these surveys are made among adults. Most of the sickle cell disease cases might have expired during their early states. Hence, it is attempted to estimate the expected frequencies of disease cases from HbS gene frequencies. Estimations were also made by considering higher levels of inbreeding among these populations.     

MHC Class II haplotypes of Colombian Amerindian tribes

We analyzed 1041 individuals belonging to 17 Amerindian tribes of Colombia, Chimila, Bari and Tunebo (Chibcha linguistic family), Embera, Waunana (Choco linguistic family), Puinave and Nukak (Maku-Puinave linguistic families), Cubeo, Guanano, Tucano, Desano and Piratapuyo (Tukano linguistic family), Guahibo and Guayabero (Guayabero Linguistic Family), Curripaco and Piapoco (Arawak linguistic family) and Yucpa (Karib linguistic family). for MHC class II haplotypes (HLA-DRB1, DQA1, DQB1). Approximately 90% of the MHC class II haplotypes found among these tribes are haplotypes frequently encountered in other Amerindian tribes. Nonetheless, striking differences were observed among Chibcha and non-Chibcha speaking tribes. The DRB1*04:04, DRB1*04:11, DRB1*09:01 carrying haplotypes were frequently found among non-Chibcha speaking tribes, while the DRB1*04:07 haplotype showed significant frequencies among Chibcha speaking tribes, and only marginal frequencies among non-Chibcha speaking tribes. Our results suggest that the differences in MHC class II haplotype frequency found among Chibcha and non-Chibcha speaking tribes could be due to genetic differentiation in Mesoamerica of the ancestral Amerindian population into Chibcha and non-Chibcha speaking populations before they entered into South America.     

Studies on several genetic hematological traits of the Mexican population. XII. Distribution of blood group antigens in twelve Indian tribes

Blood samples from 1090 Mexican Indians belonging to the Chol, Chontal, Totonac, Huastec, Mixe, Mazatec, Zapotec, Mixtec, Chinantec, Nahua, Cora and Huichol linguistic groups, were obtained and examined in regard to the following blood group antigens: A, B. M, N, P, C, c, D, E, e, Fy(a), K and Di(a). The gene frequencies were similar to what has been described for other Amerindians; high values for O, M, CDe, cDE and Duffy; low to absent Kell and presence of Diego in variable amounts. The frequency of chromosomes CDE and cDe/cde was somewhat higher than usual and some of the tribes had relatively high frequencies of the A and B antigens. It was felt that variable degrees of non-Indian admixture was at least partially responsible for this situation. A previous study dealing with the distribution of abnormal hemoglobins and glucose-6-phosphate dehydrogenase deficiency in these same tribes, had strongly suggested the possibility of some Negro admixture in the Chontal, Nahua and Cora tribes. However, this was not specifically reflected in their blood group distribution. This served to emphasize the need of investigating as many markers as possible when trying to characterize a population.     

Medical genetic study of the population of Turkmenia. VI. Intrapopulation variability from an analysis of marriage migrations and ABO and Hp marker systems

By the sampling procedure, the distribution of phenotypic and genotypic frequencies of ABO and Hp systems and the structure of intermarriage migration in Turkmen population was studied. The geographical subdivision of the Turkmen population coincided with its ethnic divergency. The main Turkmen tribes are highly isolated (the gametic index is 0.965 to 1.0) and the differences in gene frequencies between tribes are significant. The mean gene frequencies for the ABO system in the Turkmen population are: I0-0.5373, IA-0.2601, IB-0.2025, these being Hp1-0.284, Hp2-0.716 for the Hp system.     

Plasma cholinesterase studies on south-eastern Bantu of Mozambique.

Blood samples from four Bantu tribes in South-East Mozambique have been phenotyped for the plasma cholinesterase variants of the E1 locus. A control roup of 153 Portuguese residents in Mozambique have also been phenotyped. The frequencies of both the E1a and E1f genes in the Portuguese population is very similar to those in other Caucasian populations. The absence of the E1a gene in the four Bantu tribes provides more evidence of the rarity of this gene in Negroid populations. There is an increased frequency of E1f gene in all tribes as compared with previous surveys. The Ronga and Bitonga tribes have similar E1f frequencies of 0.047 and 0.048, respectively. The Shangana has an E1f frequency of 0.060, and the corresponding figure for the Chopi tribe is 0.089. The latter is the highest recorded frequency for this gene. The results give some support to the doubts concerning the affiliation of the Chopi tribe.     

Further data on the microsatellite locus D12S67 in worldwide populations: an unusual distribution of D12S67 alleles in Native Americans

We report the frequencies of alleles at the microsatellite locus D12S67 in 2 widely separated ethnic groups of the world: 2 populations from Sulawesi, an island in the Indonesian archipelago, and 5 Native American tribes of Colombia, South America. The allele frequencies in the Minihasans and Torajans of Sulawesi are similar to each other (but the modal class allele is different) and in general agreement with those reported in mainland Asian groups, but different from both Europeans and Chinese Han of Taiwan. The 5 Native American tribes (Arsario, Kogui, Ijka, Wayuu, and Coreguaje) display different allele frequencies from those seen in Sulawesi populations, in other groups from Europe and mainland Asia, and in Chinese Han of Taiwan. Native Americans exhibit a bimodal distribution of alleles, unlike other groups, with significant differences among the tribes. The Arsario and Kogui have no admixture with Europeans or Africans and are the most distinctive, while the Wayuu have the most admixture and show most similarity to other groups. The data suggest that nonadmixed Native Americans may be quite distinctive with respect to this marker. The most common allele varies across the 5 tribes, from 249 base pairs to 261 base pairs. All samples exhibit Hardy-Weinberg genotype proportions; heterozygosities are lowest in the 2 nonadmixed Native American tribes. Examination of all the available data indicates that some east Asian and southeast Asian groups are characterized by a high frequency of smaller sized D12S67 alleles, while other populations have a greater proportion of the larger sized alleles. The cumulative, though still highly restricted, population data on locus D12S67 demonstrate that it may be of considerable value in anthropological genetic studies of ethnic groups. Data are required on Native Americans outside Colombia before this marker can be used in admixture studies of this group.     

Information on dermatoglyphic systems of the toes and soles of the feet among the Kalenjins of Kenya

The frequencies of quantitative and qualitative dermatoglyphic features of the toes and soles of 108 males and 108 females of two tribes from Northern Kenya are reported. These tribes are classified among the Kalenjin. The data are compared with those from other populations.     

The dermatoglyphic characteristics of two isolated Bedouin groups from South Sinai

The dermatoglyphics of the Muzeina and Gebeliya Bedouin tribes, two small biologically isolated populations, leading a similar nomadic life under the specific conditions of the Sinai desert, were studied. The differences found between the studied samples concern particularly the frequencies of palmar and finger pattern types. These differences are in agreement with data on the origin of the tribes, a Negro and/or European admixture being evident in the Gebeliya dermatoglyphics. The coefficients of variation for some quantitative dermatoglyphic traits, presumably with a polygenic determination, are lower in the Muzeina than in the Gebeliya sample. Isolation and consanguinity may exert their influence on the dermatoglyphic traits influencing the frequencies of the corresponding genes.     

Blood groups and ABH saliva secretion in Koya Dora and Konda Kammara tribes of Andhra Pradesh

The present paper reports the distribution of blood groups and ABH saliva secretion in two Andhra tribal populations: the Koya Dora and the Konda Kammara. 100 Koya Dora and nearly 110 Konda Kammara adults of both sexes were tested for A1A2BO, MN, Rh (CcDEe) blood groups and ABH saliva secretion. The gene frequencies for A1A2BO, MN and ABH and the gene as well as chromosome frequencies for Rh (CcDEe) systems were calculated. Koya Doras show a higher incidence of A gene than B gene, while the reverse trend is seen in Konda Kammaras. Both the tribes show a high M gene frequency. No Rh(D) negative individual was found in Koya Doras, while 4.59% of Konda Kammaras are Rh(D) negative. The chromosomes CDE, CdE, cDe, cdE, Cde and cde are absent in Koya Doras, while only the four chromosomes CDE, CdE, cDe and cdE are absent in Konda Kammaras. The chromosome CDe shows the highest frequency in both the tribes. The frequency of secretors is, as usual, higher than that of nonsecretors in both the tribes. The intergroup variation between the two tribes is not statistically significant for MN, Rh (CcDEe) and ABH systems, while the difference is significant for the A1A2BO blood groups. Suitable comparisons have also been made with all the other available data from Andhra Pradesh tribal populations with respect to different systems studied. Finally Fi estimates have been calculated after Harpending et al. (1973) and Workman et al. (1974) for Koya Doras and Konda Kammaras to assess their degree of endogamy, considering the codominant systems studied, which suggest that Koya Doras are relatively more isolated than Konda Kammaras.     

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.     

Intertribal and temporal allele-frequency variation at the ABO locus among Tibeto-Burman-speaking Adi subtribes of Arunachal Pradesh, India

We studied the distribution of ABO blood group frequencies of the Galo and Mishing subtribes of the Adi tribal cluster in East Siang District, Arunachal Pradesh, India, in order to investigate the intertribal and temporal allelic variation. Blood groups O and AB showed higher frequencies (28.4%, 27.4%) in the Galo, whereas group O (45%) was predominant in the Mishing. Allele r is significantly different in the Galo (44.6%) and Mishing (60.3%). The chi-square test indicated significant deviations from Hardy-Weinberg equilibrium. Adi tribes show high heterogeneity and indicate significant temporal variation in ABO genotype frequencies in the Galo, Mishing, and Padam, whereas the Panggi, a small isolated subtribe of Adi, show similar and stable frequencies.     

怒江大峡谷及下游地区7个云南少数民族YAP位点的多态性研究

本文以怒江大峡谷及下游地区的独龙族、怒族、僳僳族、阿昌族、景颇族、德昂族和傣族7个云南特有少数民族为对象,利用PCR分型法筛查Y染色体特异区YAP位点的多态性分布。结果显示：怒族的YAP^ 频率为1.82%,景颇族为12.50%,傣族为10.00%,其他4个民族群体均为YAP^-。     

Electrophoretic and isoelectric focusing studies in Brazilian Indians: data on four systems

Three-hundred ninety-nine individuals living in seven populations of two Brazilian Indian tribes (Macushi and I?ana River Indians) were tested for the phosphoglucomutase 1 (PGM1), properdin factor B (BF), haptoglobin (HP), and alpha-1-antitrypsin (PI) systems. We observed significant internal heterogeneity in the two tribes for the PGM1 alleles and in the Macushi for the HP markers. Frequencies in three of the four systems (the exception being BF) also show clear differences in the Macushi and I?ana River Indians. Compared with other ethnic groups, South American Indians generally present high frequencies of PGM1*1B, BF*S, HP*1S, and PI*M3. On the other hand, PGM1*1A, PI*M1, and PI*M2 are reduced, and HP*1F is absent or rare. This is the first report about HP subtypes among American Indians.