Anatomic site and immune function correlate with relative cytokine mRNA expression levels in lymphoid tissues of normal rhesus macaques.

Reverse transcriptase real-time polymerase chain reaction was used to determine pro-inflammatory, anti-viral and immunoregulatory cytokine mRNA expression levels in peripheral blood mononuclear cells (PBMC) of healthy juvenile, adolescent and adult rhesus macaques. Few age-related changes in cytokine mRNA expression levels were observed. Expression of interleukin 2 and Mx, a type I interferon-inducible gene, decreased with age, whereas interleukin 4 and macrophage inflammatory protein 1 (MIP-1) alpha and beta mRNA levels increased in older monkeys. Independent of age, the pro-inflammatory cytokines [tumour necrosis factor alpha (TNF-alpha) and chemokines] were expressed at higher mRNA levels in PBMC than the immunoregulatory cytokines (interleukins 2, 4, 12). Pro-inflammatory cytokine mRNA expression levels were highest in lymphoid tissues draining mucosal surfaces. Thus, a correlation exists between cytokine mRNA levels in lymphoid tissues and the anatomical site.

Genetic variation of recent Alu insertions in human populations.

The Alu family of interspersed repeats is comprised of over 500,000 members which may be divided into discrete subfamilies based upon mutations held in common between members. Distinct subfamilies of Alu sequences have amplified within the human genome in recent evolutionary history. Several individual Alu family members have amplified so recently in human evolution that they are variable as to presence and absence at specific loci within different human populations. Here, we report on the distribution of six polymorphic Alu insertions in a survey of 563 individuals from 14 human population groups across several continents. Our results indicate that these polymorphic Alu insertions probably have an African origin and that there is a much smaller amount of genetic variation between European populations than that found between other population groups.

Sequence diversity and chromosomal distribution of "young" Alu repeats.

Members of the recently inserted human-specific (HS)/predicted variant (PV) subfamily of Alu elements were sequenced. A number of these Alu elements share greater than 98% sequence identity with the subfamily consensus sequence, and they are flanked by perfect 5' and 3' direct repeats ranging in size from 6 to 15 nucleotides (nt). Based on the low number of random mutations, the estimated average age of these elements was calculated to be 1.5 million years (Myr). All the young Alu subfamily members were restricted to the human genome, as judged by polymerase chain reaction (PCR) amplification of human and non-human primate DNA samples using the unique flanking sequences specific for each Alu element. The chromosomal locations of several Alu elements belonging to the young subfamilies, designated as HS/PV and Sb2, were determined by PCR amplification of DNA samples from human/rodent somatic cell hybrid panels. A statistical analysis of the chromosomal distribution pattern showed that the recently inserted Alu elements appear to integrate randomly in the human genome.

Dispersion and insertion polymorphism in two small subfamilies of recently amplified human Alu repeats.

Newly isolated members of two recently propagated (young) Alu subfamilies were examined for sequence diversity and insertion polymorphism in primate genomes. The smaller subfamily (termed HS-2) is comprised of approximately 5 to 25 members, while the larger (termed Sb2) includes approximately 125 to 600 members. Individual members of these Alu subfamilies share distinguishing sets of diagnostic mutations, are well-conserved relative to each other, and have expanded in the human lineage. At least one member from each subfamily is known to be polymorphic in humans. Three newly characterized HS-2 Alu family members as well as three Sb2 Alu repeats are monomorphic (fixed) in humans. The existence of a number of Alu subfamilies that have amplified in parallel within the human genome provides compelling evidence for the simultaneous activity of multiple dispersed Alu source genes.

Assembly of high-resolution bacterial artificial chromosome, P1-derived artificial chromosome, and cosmid contigs.

The generation of contiguous physical maps is often complicated by a variety of factors including the type of cloning system used. Here we describe procedures for the isolation, rapid characterization, and physical mapping of large-insert recombinant bacterial clones from total human genomic BAC (bacterial artificial chromosome) and PAC (P1-derived artificial chromosome) libraries containing clones with an average insert size of 150 kbp. After initial isolation, the clones were subjected to a variety of fingerprinting procedures including inter-Alu PCR, semiautomated fluorescent finger-printing, and EcoRI restriction fragment mapping. Individual BAC and PAC clones were also used as probes to interrogate arrayed chromosome 19-specific cosmid libraries. The combination of analyses facilitated the identification of chromosome-specific large-insert clones as well as the construction of a large (1.2 Mb) high-resolution BAC, PAC, and cosmid contig in 19q13.2, spanning the region from the carcinoembryonic antigen gene family to the X-ray repair cross complementing 1 DNA repair gene. This type of approach directly demonstrates the utility of large-insert recombinant bacterial clones for the construction of contiguous physical maps of entire chromosomes.

African origin of human-specific polymorphic Alu insertions.

Alu elements are a family of interspersed repeats that have mobilized throughout primate genomes by retroposition from a few "master" genes. Among the 500,000 Alu elements in the human genome are members of the human-specific subfamily that are not fixed in the human species; that is, not all chromosomes carry an Alu element at a particular locus. Four such polymorphic human-specific Alu insertions were analyzed by a rapid, PCR-based assay that uses primers that flank the insertion point to determine genotypes based on the presence or absence of the Alu element. These four polymorphic Alu insertions were shown to be absent from the genomes of a number of nonhuman primates, consistent with their arising as human genetic polymorphisms sometime after the human/African ape divergence. Analysis of 664 unrelated individuals from 16 population groups from around the world revealed substantial levels of variation within population groups and significant genetic differentiation among groups. No significant associations were found among the four loci, consistent with their location on different chromosomes. A maximum-likelihood tree of population relationships showed four major groupings consisting of Africa, Europe, Asia/Americas, and Australia/New Guinea, which is concordant with similar trees based on other loci. A particularly useful feature of the polymorphic Alu insertions is that the ancestral state is known to be the absence of the Alu element, and the presence of the Alu element at a particular chromosomal site reflects a single, unique event in human evolution. A hypothetical ancestral group can then be included in the tree analysis, with the frequency of each insertion set to zero. The ancestral group connected to the maximum-likelihood tree within the African branch, which suggests an African origin of these polymorphic Alu insertions. These data are concordant with other diverse data sets, which lends further support to the recent African origin hypothesis for modern humans. Polymorphic Alu insertions represent a source of genetic variation for studying human population structure and evolution.

A consensus Alu repeat probe for physical mapping.

Physical mapping of the human genome involves a variety of complex hybridization-based procedures, some of which rely upon the ability to separate human clones derived from human-rodent hybrid cell lines from those that contain background rodent-derived DNA sequences. The ability to block the repetitive element (Alu repeat) portion of inter-Alu PCR products derived from a variety of complex sources is also crucial for the isolation of unique DNA sequences. Here we report the construction and characterization of a new consensus Alu repeat probe (pPD39) designed for these purposes.

A two-dimensional YAC pooling strategy for library screening via STS and Alu-PCR methods.

We have developed a simple two-dimensional YAC pooling strategy to facilitate YAC library screening via STS and Alu-PCR approaches. The method has been implemented using the human total genomic YAC library of Olson and coworkers, and its validity tested by isolation of many chromosomes 19- and 21-specific YACs. The Alu-PCR approach is notable in that it is hybridization-based, such that PCR primer pairs do not need to be repeatedly synthesized and tested for each screening step.