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Katz, Kaplan, Kaplansky, Kahan, Catznelson, Kohn, Myer HaKohen. Katz, Kaplan, Kaplansky, Kahan, Catznelson, Kohn, Myer HaKohen.


Members with those surnames above that were tested on FTDNA http://www.ftdna.com, turn to be 'positive' for the Cohen Modal Cluster Haplotype. They all share the same Cohen Unique-Event Polymorphism and have the J2 Cohanim signature above. Members with those surnames above that were tested on FTDNA http://www.ftdna.com, turned 'positive' for the Cohen Modal Cluster Haplotype. They all share the same Cohen Unique-Event Polymorphism and have the J2 Cohanim signature above.


Any one-mutation neighbours from the J1 Standard (CMH) above is considerate from the same Cohen Unique-Event Polymorphism (UEP). Those who macth the Cohen Unique-Event Polymorphism belongs to the single Cohen Modal Cluster Haplotype (CMCH).<ref>Haim Ben-Amit/Rambam Medical Centre, Haifa 31096, Israel; Turdor Parfitt / Any one-mutation neighbours from the J1 Standard (CMH) above is considerate from the same Cohen Unique-Event Polymorphism (UEP). Those who macth the Cohen Unique-Event Polymorphism belongs to the single Cohen Modal Cluster Haplotype (CMCH).<ref>Haim Ben-Amit/Rambam Medical Centre, Haifa 31096, Israel; Turdor Parfitt /

Revision as of 23:30, 18 February 2008

Y-chromosomal Aaron is the name given to the hypothesised most recent common ancestor of many of the patrilineal Jewish priestly caste known as Kohanim (singular "Kohen", "Cohen", or Kohane). In the Hebrew Bible this ancestor is identified as Aaron, the brother of Moses.

Research published in 1997 and thereafter has indicated that a large proportion of contemporary Jewish Kohanim share a set of Y chromosomal genetic markers, known as the Cohen Modal Haplotype, which may well derive from this single common ancestor.

Background

Although membership in the Jewish community is traditionally passed maternally (see: Who is a Jew?), membership in the group that originally comprised the Jewish priesthood ("Kohens" or Kohanim), is patrilineal, and modern Kohens claim descent from Aaron, brother of Moses.

For human beings the normal number of chromosomes is 46, of which 23 are inherited from each parent. Two chromosomes, the X chromosome and Y chromosome, determine gender. Women have two X chromosomes, one inherited from their mother, and one inherited from their father. Men have an X chromosome inherited from their mother, and a Y chromosome inherited from their father.

Males who share a common patrilineal ancestor should also share a Y chromosome, diverging only with respect to accumulated mutations. Since Y-chromosomes are passed from father to son, all Kohanim men should theoretically have almost identical Y chromosomes; this can be tested with a genealogical DNA test. As the rate that mutations accumulate on the Y chromosome is relatively constant, scientists can estimate the elapsed time since two men had a common ancestor. (See molecular clock.)

Initial studies

The Cohen hypothesis was first tested by Prof. Karl Skorecki and collaborators from Haifa, Israel, in 1997. In their study, "Y chromosomes of Jewish priests," published in the journal Nature, they found that the Kohanim appeared to share a different probability distribution compared to the rest of the Jewish population for the two Y-chromosome markers they tested (YAP and DYS 19); and that furthermore the probabilities appeared to be shared by both Sephardi and Ashkenazi Cohens, pointing to a common Cohen population origin before the Jewish diaspora at the time of the Roman empire.

A subsequent study the next year (Thomas MG et al, 1998) increased the number of Y-STR markers tested to six, as well as testing more SNP markers. Again, they found that a clear difference was observable between the Cohanim population and the general Jewish population, with many of the Cohen STR results clustered around a single pattern they named the Cohen Modal Haplotype:

  xDE xDE,PR Hg J CMH.1 CMH CMH.1/HgJ CMH/HgJ
Ashkenazi Cohanim (AC): 98.5% 96% 87% 69% 45% 79% 52%
Sephardi Cohanim (SC): 100% 88% 75% 61% 56% 81% 75%
Ashkenazi Israelites (AI): 82% 62% 37% 15% 13% 40% 35%
Sephardi Israelites (SI): 85% 63% 37% 14% 10% 38% 27%

Here, becoming increasingly specific, xDE is the proportion who were not in Haplogroups D or E (from the original paper); xDE,PR is the proportion who were not in haplogroups D, E, P, Q or R; Hg J is the proportion who were in Haplogroup J (from the slightly larger panel studied by Behar et al (2003)); CMH.1 means "within one marker of the CMH-6"; and CMH is the proportion with a 6/6 match. The final two columns show the conditional proportions for CMH.1 and CMH, given membership of Haplogroup J.

The data shows that the Cohanim were more than twice as likely to belong to Haplogroup J than the average non-Cohen Jew; and of those who did belong to Haplogroup J, the Cohanim were more than twice as likely to have an STR pattern close to the CMH-6, suggesting a much more recent common ancestry for most of them compared to an average non-Cohen Jew of Haplogroup J.

Thomas et al dated the origin of the shared DNA to approximately 3,000 years ago (with variance arising from different generation lengths). The techniques used to find Y-chromosomal Aaron were first popularized in relation to the search for the patrilineal ancestor of all contemporary living humans, Y-chromosomal Adam.

Responses

The finding led to excitement in religious circles, with some seeing it as providing some "proof" of the historical veracity of the Bible or other religious convictions, but there was also criticism that the paper's evidence was being overstated.


The most basic difficulty with Y-chromosomal Aaron being identified with J-M267 (J1) is that Abraham and the Semitic tribes originate from Southern Arabia/Ethiopia and not the Levant or Mesopotamia. Archaeologists have mapped the ancient Semitic tribes to modern Ethiopia, Yemen, Oman, United Arab Emirates, and Qatar. The only exception to these were the tribes of Aram (Aram-Damascus), Asshur, and Elam as small cluster groups in Mesopotamia overshadowed by Assyria and Babylon (both listed as Hamitic; see Genesis 10). This suggests a Southern Arabian/Ethiopian origin for the Semites and Abraham, which does not correspond to the evolution of haplogroup J in the Levant.


A secondary difficulty with the dating of the CMH (which properly can only include J-M267) is that the traditional date for Abraham is not known, but often cited as ca. 2200-2000 BCE; Aaron and Moses were exactly 7 generations after Abraham (Exodus 6:14-25). The traditional date for the Conquest of Canaan is 1450 BCE. Moses and Aaron would have lived before the Conquest. Thomas' date of 3000 BP or 1000 BCE falls short of the dates of the same biblical tradition upon which the Cohen tradition was founded.

Cohens in other haplogroups

Behar's 2003 data points to the following Haplogroup distribution for Cohens as a whole:

Hg: E3b G2c H I1b J K2 Q R1a1 R1b Total
AC 3 0 1 0 67 2 0 1 2 76
4% 1½% 88% 2½% 1½% 2½% 100%
SC 3 1 0 1 52 2 2 3 4 68
4½% 1½% 1½% 76% 3% 3% 4½% 6% 100%

The detailed breakdown by 6-marker haplotype (the paper's online-only table B) suggests that some at least even of these groups (eg E3b, R1b) contain more than one distinct Cohen lineage. It is possible that still further other lineages may also exist, but were not captured in the sample.

Does a CMH prove Cohen ancestry?

One source of early confusion was a widespread popular notion that only Cohens or only Jews could have the Cohen Modal Haplotype. It is now clear that this is not the case. The Cohen Modal Haplotype, whilst notably frequent amongst Cohens, is also far from unusual in the general populations of haplogroups J1 and J2 with no particular link to the Cohen ancestry. These haplogroups occur widely throughout the Middle East and beyond . So whilst many Cohens have haplotypes close to the CMH, a far larger number of such haplotypes worldwide belong to people with no likely Cohen connection at all.

Statistically the value of matching the CMH can be assessed using Bayes' theorem, which in its odds form can be written:

P ( C | D , I ) P ( C | D , I ) = P ( C | I ) P ( C | I ) P ( D | C ) P ( D | C ) {\displaystyle {\frac {P(C|D,I)}{P({C^{'}}|D,I)}}={\frac {P(C|I)}{P({C^{'}}|I)}}\cdot {\frac {P(D|C)}{P(D|{C^{'}})}}}

In words, this says that the odds in favour of Cohen ancestry C (ie the probability of having Cohen ancestry, divided by the probability of not having Cohen ancestry), having observed some piece of data D, is given by the odds one would assign given only one's initial information I, multiplied by the probability of having observed D if C is true, divided by the probability of having observed D if C is false.

(In fact, for convenience we shall work with the reciprocal of this equation, ie work in terms of odds against, rather than odds on).

The proportion of the whole male Jewish population that has Cohen ancestry has been estimated at 5%. So if we take that 5% as our initial estimate of the probability of shared Cohen ancestry, then on the basis of the data above:

  • Not belonging to haplogroups D or E improves the odds for a Sephardi Jew from 19/1 against to (19/1)*(0.85/1.00) = 16.2/1 against (a 5.8% probability)
  • Not belonging to haplogroups D,E,P,Q or R takes the odds to (19/1)*(0.63/0.88) = 13.6/1 against (6.8% probability).
  • Membership of Haplogroup J improves the odds to (19/1)*(0.37/0.75) = 9.4/1 against (9.6% probability).
  • Being within the CMH.1 group takes the odds to (19/1)*(0.14/0.61) = 4.4/1 against (18.7% probability).
  • A full 6/6 match takes the odds to (19/1)*(0.10/0.56) = 3.4/1. (22.7% probability).

Even a full 6/6 match for the 6 marker CMH thus cannot "prove" Cohen ancestry. It can only somewhat strengthen a previously existing belief. But for populations where the background probability assessment of shared Cohen ancestry must be vanishingly low, such as almost all non-Jews, even a full 6/6 match makes only a small difference. For individuals in such populations the CMH likely indicates Haplogroup J, but a completely different ancestry to the Cohanim.

Higher resolution

The discussion above applies to the so far published scientific papers. However, in principle some more resolution could be obtained by determining the Cohen haplogroup more narrowly, and/or testing more Y-STR markers to determine whether there is an extended characteristic Cohen haplotype.

Haplogroup placement

The largest population of Kohanim which most closely match the Cohen haplotype cluster are believed to belong to subgroup J1 of haplogroup J.

Individuals with the genetic Cohen Modal Haplotype can be found in subgroup J2 as well, and occasionally in more genealogically distant haplogroups too; however these are not closely related to the cluster in Haplogroup J1.

The subdivision of J2 which most closely matches the genetic signature of the J1 Cohens is subclade J2a1b, a large fraction of members of which will also have a 6/6 match for the 6-marker CMH. However, this is an example of haplotype convergence: Basically the haplotype "distribution" within one lineage (Haplogroup) overlaps with the haplotype "distribution" of another lineage - its like overlapping branches from two different trees. The more likely reason for the match is convergence (coincidence) or because sharing a common haplotype in the same lineage (Haplogroup). Convergence: Mutation is a random process and over thousands of years can occur in different lines so that by coincidence different "lines" end up with "matching" haplotypes. This accidental agreement is called convergence. (The more markers that are tested, the less likely it is that convergence will be observed). of different genetic lines, which it is believed have been not been closely related for at least the last 10,000 years; the group in J2a1b who have the 6-marker CMH are devoid of any Cohen traditions in their families.

On the other hand, there are families in Haplogroup J2 who do have a Cohen religious tradition and are proud of it (as there are in several other haplogroups, including Haplogroup R1b). The haplotypes of these Haplotype J2 Kohanim cluster in a unique, small offshoot of J2a1*, close to haplotypes of the J2a1k clade, not the J2a1b clade. These J2 Kohanim typically have a 4/6 match for the 6-marker CMH (with DYS19=15 rather than 14, and DYS388=15 rather than 16). They do not match the 12-marker J1-extended CMH, and they do not share a common ancestor with the J1 Kohanim in a Biblical timeframe; but they are equal co-inheritors of a patrilineal tradition which appears to date back well before the Diaspora.

As it happens, three of the four markers for which they do match the CMH-6 were the markers tested by Malaspina et al (2001). This appears to explain the finding of that paper that "typing a limited number of Italian Cohanim (A. Novelletto unpublished obs.) for the STRs used here, we determined that the Cohen Modal Haplotype ('an important component in the sharing of Ashkenazic and Sephardic Israelite Y chromosomes', Thomas et al. 2000) does indeed belong to network 1.2" (ie the population having DYS413a,b<=18, which is the signature of the J2a1 subclades).

The Cohen Modal Cluster Haplotype

The Cohen Modal Cluster Haplotype (CMCH) is the name used to define a category that belongs to Cohanim males, J1 and J2, descendents from a commom ancestral type, strongly believed to be Aaron HaKohen, the first Priest, brother of Moses, and father of all Cohanim. Cohanim chromosomes are homogeneous. What characterize the Cohen Modal Cluster Haplotype(CMCH) is a Y-Chromossome-Especific variation at six micro-satellites (repeats of short nucleotides sequences) called Unique Event Polymorphism which is a genetic marker that corresponds to a mutation that is so infrequently, that all individuals who share the marker, worldwide, have inherited it from the same common ancestor, and the same single mutation event.

Examples

Because of microsatellite instability, it was useful to define a modal cluster, of six related chromosomes as the Cohen Modal Haplotype (CMH-6) used now as standard signature and all of its one-mutation neighbours at the microsatellite loci, which all share the same Cohen Unique Event Polymorphism (UEP). The distribution of allele sizes within Cohen UEP group, at the trinucleotide microsatellite DYS388 indicates a departure from the stepwise mutation modal. Because this modal underlies the method used to estimate the coalescence time of Cohen chromosomes, the DYS388 was 'dropped' and not considerate from the analysis.

Example:DYS  = 393 390 19 391 392 
J1 Standard CMH– 12 23 14 10 11 (Cohen Unique-Event Polymorphism) 
J2 Cohanim     – 12 23 15 10 11 (Cohen Unique-Event Polymorphism) 
Katz, Kaplan, Kaplansky, Kahan, Catznelson, Kohn, Myer HaKohen.

Members with those surnames above that were tested on FTDNA http://www.ftdna.com, turned 'positive' for the Cohen Modal Cluster Haplotype. They all share the same Cohen Unique-Event Polymorphism and have the J2 Cohanim signature above.

Any one-mutation neighbours from the J1 Standard (CMH) above is considerate from the same Cohen Unique-Event Polymorphism (UEP). Those who macth the Cohen Unique-Event Polymorphism belongs to the single Cohen Modal Cluster Haplotype (CMCH). PS: Even counting the DYS388 as an one-step mutation either on the stepwise modal or infinite alleles modal, those J2 Cohanim above still share the Cohen Unique Event Polymorphism, because their values in DYS388=15 rather than 16 of the J1 CHM Standard 6 marks.

Coalescence Time

It is interesting to estimate the correct time at which Cohen chromossomes were derived from a commom ancestral chromossome (coalescence time). Under 'stepwise mutations' the average squared difference (ASD) in allele size among all current chromossome and the ancestral haplotype, averaged over loci, has an expectation of T, where is the mutation rate and T the coalescence time. Taking the Ashkenazic and Sephardic Communities as a whole, the value for ASD is 0.2226. Assuming a mutation rate of 0.0021, this gives a estimate of 106 generations time of 25 (30) years gives an estimate of 2,619 (3,180) years before present, dating the coalescence of the Cohanim chromossomes to between the Exodus and the destruction of the first Temple in 586 BC. Estimates based on the Ashkenazic and Sephardic samples taken separately are 2,619 (3,142) and 2,684 (3,221) years before present, respectively. To obtain confidence intervals on the distance between the ancestral and sampled chromossomes, it was noted that most non-ancestral haplotypes are singletons, indicating that the genealogy connecting Cohen chromossomes is more like the 'star genealogy' characteristic of 'rapid growth' than the other correlated genalogy characteristic of constant size populations. To obtain true confidence intervals in this case, (M) mutations occur during the 106 generations, with (M) being a Poisson random variable with parameter 106. The number of mutations increasing allele size (D) is drawn from a binomial distribution with parameters 0.5 and (M) leading to the distance D (2dm). In a star genealogy, there are 485 (the number of loci multiplied by the sample size) observations of D. Confidence intervals are obtained by repeating this process 1,000 times and taking the associated 2.5 and 97.5 pecentiles, leading to a 95% confidence interval of 84-130 generations for the combined Ashkenazic and Sephardic samples or for a generations time of 25 years, only 2,100-3,250 years before present. The 95% confidence interval places the origin of priestly Y-Chromossomes, in J1 and J2, sometime during or shortly before the first Temple period in Jewish history (2,100-3,250).According to Jewish Tradition, following the Exodus from Egypt, the tribe of Levi, of which Moses was a member, were assigned special religious responsabilities, and males descendents of Aaron, his brother, were selected to serve as Priests (Cohanim).

More detailed Cohen haplotypes

In the table below, the first line gives the original 6 marker Cohen Modal Haplotype (CMH-6), which was the basis for the original published papers. The second gives an extended 12 marker haplotype (CMH-12) informally released by the private company FTDNA, based on further work by much of the same research team. It has not yet been peer group reviewed by other scientists or published in the open technical literature.

The next sequence of rows identify other 6-marker haplotypes in haplogroup J found to occur more than once in the sample of 145 Cohanim tested in Behar et al (2003) (table B (web-only) in that paper). Probable extensions of these haplotypes to 12 markers are shown, where it has been possible to find corresponding clusters of Cohen-type names in publicly accessible DNA databases, together with the apparent sub-clade of haplogroup J. This is more possible for the apparently Ashkenazi clusters than for Sephardis, who are much less strongly represented in the databases.

Hg Clade or cluster DYS
393
DYS
390
DYS
19
DYS
391
DYS
385a
DYS
385b
DYS
426
DYS
388
DYS
439
DYS
389i
DYS
392
DYS
389ii
AC SC Some DNA
matches
  CMH-6 12 23 14 10       16     11      
J1 CMH-12 12 23 14 10 13 15 11 16 12 13 11 30 47% 52% 8EZ7F
J2 J2a1* 12 23 15 10 14 17 11 16 12 14 11 30 13% 0 XWPTP
J2 J2b 12 24 15 10 15 17 11 15 12 12 11 29 11% 0 F6FSU
J2 J2a1* "pre-k" 12 23 15 10 14 17 11 15 12 13 11 29 5% 0 645CH
J2 J2a1k 12 24 15 9       16   13 11 29 0 6%
J1 J1 "388=13" 12 23 14 10       13     11   0 6%
J1 modal 12 23 14 10 13 15 11 16 11 13 11 30    
J2 modal 12 23 14 10 13 15 11 15 11 13 11 30    
J2 J2a1b 12 23 14 10 13 17 11 16 11 13 11 30

Finally, for comparison, the 12-marker modal haplotypes for the haplogroups J1 and J2 are also shown. It is apparent that in both cases, their haplotype clusters are also centred very close to the Cohen modal haplotype. However, because of the much greater time that has elapsed since the mutations occurred that define the haplogroups, there has been much more time for Y-STR mutations to build up; so, although they have almost the same centre as the Cohen cluster, the J1 and J2 haplotype clusters are much more diffusely spread out. Thus although the CMH-6 is also very near to the most probable haplotype for both J1 and J2, its occurrence frequency is only about 1 to 8% amongst arbitrary members of haplogroup J with no particular Cohen connection.

Other carriers of the DNA

Critics of the theory point out that the Cohen Modal Haplotype has also been found in significant numbers in groups of non-Jews, notably Italians. However proponents of the theory are quick to explain these anomalies. They state that history records the migration of large numbers of Jews to Italy who married and took part in building the Colosseum.

However, the Cohen Haplotype has also been found among significant numbers of non-Jewish Arab and Kurdish populations. Although this too could be explained in part by miscegenation, assimilation, and conversionsh There is an alternate possibility that the marker precedes all of these populations and is a precursor to some common ancestral group.

Lemba

The Cohen Modal Haplotype has also been found in the Lemba of Southern Africa, who have a tradition of Jewish ancestry (Thomas MG et al 2000).

Kurds

Main article: Genetic origins of the Kurds

The Cohen Modal Haplotype has also been found in some groups of Kurds. There are a number of Kurdish Jews.

Y-chromosomal Levi?

A similar investigation was made with men who consider themselves Levites. Whereas the priestly Kohanim are considered descendants of Aaron, who in turn was a descendant of Levi, son of Jacob, the Levites (a lower rank of the Temple) are considered descendants of Levi through other lineages. Levites should also therefore share common Y-chromosomal DNA.

The investigation of Levites found high frequencies of multiple distinct markers, suggestive of multiple origins for the majority of non-Aaronid Levite families. One marker, however, present in more than 50% of Eastern European (Ashkenazi) Jewish Levites points to a common male ancestor or very few male ancestors within the last 2000 years for many Levites of the Ashkenazi community. This common ancestor belonged to the haplogroup R1a1 which is typical of Eastern Europeans, rather than the haplogroup J of the Cohen modal haplotype, and most likely lived at the time of the Ashkenazi settlement in Eastern Europe. .

The E3b1 haplogroup has been observed in all Jewish groups world wide. It is considered to be the second most prevalent haplogroup among the Jewish population. According to one major paper, http://www.familytreedna.com/pdf/Behar_contrasting.pdf. It has also been observed in moderate numbers among individuals from Ashkenazi, Sephardic and Samaritan backgrounds that contain the E3b1 haplogroup, having a tradition of descending from the tribe of Levi, suggesting that the E3b1 Levites may have existed in Israel before the Diaspora of 70 C.E.

The Samaritan community is a small, isolated, and highly endogamous group today numbering some 650 members who have maintained extensive genealogical records for the past 13–15 generations. Since the Samaritans maintain extensive and detailed genealogical records, it is possible to construct accurate pedigrees and specific maternal and paternal lineages. The Samaritan community in the Middle East survives as a distinct religious and cultural sect and constitutes one of the oldest and smallest ethnic minorities in the world. Y-Chromosome studies have shown that the majority of Samaritans belong to haplogroups J1 and J2 while the Samaritan Cohanim belong to haplogroup E3b1a.. In 1623-1624 the last member of the high-priestly family, which claimed descent from the eldest son of Aaron, died. The office was then given to the junior branch, descended from Uzziel, the son of Kohath. Since that date the priest has called himself "ha-kohen ha-Lewi," (Heb. "The Levite Priest") instead of "ha-kohen ha-gadol" (Heb. "The High Priest") as in previous times. The approximately 650 individuals comprising the total group of present day Samaritans trace their ancestry over a period of more than 2,000 years to the Biblical Israelite tribes of Ephraim, Menashe and Levi. As a religious sect, the Samaritans broke away from the main stream of Judaism around the fifth century B.C.E.

See also

References

  1. ^ Skorecki, K (1997). "Y chromosomes of Jewish priests". Nature. 385: 32. PMID 8985243. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  2. ^ Thomas, MG (1998). "Origins of Old Testament priests" (PDF). Nature. 394: 138–40. PMID 9671297. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  3. ^ Behar, DM (2003). "Multiple Origins of Ashkenazi Levites: Y Chromosome Evidence for Both Near Eastern and European Ancestries". Am. J. Hum. Genet. 73: 768–779. PMID 13680527. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  4. Kleiman, Rabbi Yaakov (2000). "The Cohanim/DNA connection".
  5. Clark, David (2002). "Cohanim Modal Haplotype (CMH) finds the Ten Lost Tribes! (among Iraqi Kurds, Hungarians, and Armenians)".
  6. Zoossmann-Diskin, Avshalom (2001). "Are today's Jewish priests descended from the old ones?". Journal of Comparative Human Biology. 51 (2–3): 156–162. (Summary)
  7. Yohanan Aharoni, et al, The Macmillan Bible Atlas, Macmillan Publishing: New York, 1993, p. 21.
  8. Nebel, A (2001). "The Y chromosome pool of Jews as part of the genetic landscape of the Middle East". Am. J. Hum. Genet. 69: 1095–1112. PMID 11573163. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  9. Semino, O (2004). "Origin, Diffusion, and Differentiation of Y-Chromosome Haplogroups E and J: Inferences on the Neolithization of Europe and Later Migratory Events in the Mediterranean Area". Am. J. Hum. Genet. 74: 1023–1034. PMID 15069642. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  10. The private company FTDNA has indicated that the CMH Kohanim cluster is associated with J1 rather than J2. Although as of March 2007 no scientific paper has yet been published disclosing their full data, the conclusion matches a clustering of Cohen-type names close to Ysearch G6839 in very much more limited data from various sources that are publicly accessible.
  11. ^ Schrack, Bonnie (13 April 2007). "Cohen does not equal CMH,CMH does not equal Cohen -- only in J1 do they coincide". GENEALOGY-DNA-L Archives. Retrieved 2007-04-15.
  12. Malaspina, P (2001). "A multistep process for the dispersal of a Y chromosomal lineage in the Mediterranean area". Ann. Hum. Genet. 65 (Pt 4, July): 339–49. PMID 11592923. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  13. Mark G. Thomas / The Centre for Genetic Anthropology, Departament of Biology and Anthropology, University College London, London WC1E 6BT, UK;
  14. Haim Ben-Amit/Rambam Medical Centre, Haifa 31096, Israel; Turdor Parfitt / University of London, London WC1H OXC, UK;
  15. Origins of Old Testaments Priests - Nature , Volume 394 -9 de July 1998. Authors: Karl Skorecki / Bruce Rapparport Faculty of Medicine and Research Institute, Technion, Haifa 31096, Israel; Mark G. Thomas / The Centre for Genetic Anthropology, Departament of Biology and Anthropology, University College London, London WC1E 6BT, UK; Haim Ben-Amit/Rambam Medical Centre, Haifa 31096, Israel; Turdor Parfitt / University of London, London WC1H OXC, UK; Neil Brandman and David. B. Goldstein/ University of Oxford, Oxford OX1 3PS, UK
  16. THE DNA & TRADITIONAL - A The Genetic Link to the Ancient Hebrews book/ Devora Publishing from Jerusalem and New York (2005)Author: Rabbi Yaakov Kleiman - Director of The Center of Kohanim located in the Old City of Jerusalem. The author met with the researches, and help collect samples for the studies. Rabbi Yaakov Kleiman is the principal speaker for the next Internacinal Jewish Genealogical Society Convention, held in Jerusalem every year, since 2002. Rabbi Yaakov Kleiman is the director of the Cohen-Levi Organization. http://www.cohen-levi.org
  17. Nomenclature and analogues from Schrack, B. "The Y-Haplogroup J DNA Project". FTDNA.com. Retrieved 2007-04-24. {{cite web}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  18. Thomas, MG (2000). "Y chromosomes traveling south: the Cohen modal haplotype and the origins of the Lemba--the "Black Jews of Southern Africa"". Am. J. Hum. Genet. 66: 674–86. PMID 10677325. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  19. Brook, Kevin Alan, The Genetic Bonds between Kurds and Jews, Netewe, January 19, 2002.
  20. Behar, DM (2004). "Contrasting patterns of Y chromosome variation in Ashkenazi Jewish and host non-Jewish European populations" (PDF). Hum. Genet. 114: 354–365. PMID 14740294. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  21. Nebel, A (2004). "Y chromosome evidence for a founder effect in Ashkenazi Jews". European Journal of Human Genetics. 13 (3): 388–91. PMID 15523495. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  22. Shen, P (2004). "Reconstruction of Patrilineages and Matrilineages of Samaritans and Other Israeli Populations From Y-Chromosome and Mitochondrial DNA Sequence Variation" (PDF). Human Mutation. 24: 248–260. PMID 15300852. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  • Elkins, JE et al (2005). "An Updated World-Wide Characterization of the Cohen Modal Haplotype". ASHG meeting October 2005 (abstract)

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