Polytene chromosome

About: Polytene chromosome is a research topic. Over the lifetime, 2667 publications have been published within this topic receiving 88255 citations.

A Polytene Chromosome Analysis of the Anopheles gambiae Species Complex

Abstract: Field-collected specimens of all known taxa in the Anopheles gambiae complex were analyzed on the basis of chromosome inversions with reference to a standard polytene chromosome map. The phylogenetic relationships among the seven described species in the complex could be inferred from the distribution of fixed inversions. Nonrandom patterns of inversion distribution were observed and, particularly on chromosome arm 2R, provided evidence for genetically distinct populations in A. gambiae, A. arabiensis, and A. melas. In A. gambiae from Mali, stable genetic differentiation was observed even in populations living in the same region, suggesting a process of incipient speciation which is being confirmed by studies with molecular markers. The possible role of chromosome differentiation in speciation of the A. gambiae complex and in the emergence of distinct chromosomal forms within the nominal species is discussed in relation to human malaria.

Chromatin Loosening by Poly(ADP)-Ribose Polymerase (PARP) at Drosophila Puff Loci

Abstract: Steroid response and stress-activated genes such as hsp70 undergo puffing in Drosophila larval salivary glands, a local loosening of polytene chromatin structure associated with gene induction. We find that puffs acquire elevated levels of adenosine diphosphate (ADP)-ribose modified proteins and that poly(ADP)-ribose polymerase (PARP) is required to produce normal-sized puffs and normal amounts of Hsp70 after heat exposure. We propose that chromosomal PARP molecules become activated by developmental or environmental cues and strip nearby chromatin proteins off DNA to generate a puff. Such local loosening may facilitate transcription and may transiently make protein complexes more accessible to modification, promoting chromatin remodeling during development.

SMC complexes: from DNA to chromosomes

Abstract: SMC (structural maintenance of chromosomes) complexes are found in all living organisms and include condensin, cohesin and the SMC5–SMC6 complex. Recent mechanistic insight into these ring-shaped protein machines, which topologically encircle DNA, shed light on how they function to mediate chromosome condensation, sister chromatid cohesion and DNA repair. SMC (structural maintenance of chromosomes) complexes — which include condensin, cohesin and the SMC5–SMC6 complex — are major components of chromosomes in all living organisms, from bacteria to humans. These ring-shaped protein machines, which are powered by ATP hydrolysis, topologically encircle DNA. With their ability to hold more than one strand of DNA together, SMC complexes control a plethora of chromosomal activities. Notable among these are chromosome condensation and sister chromatid cohesion. Moreover, SMC complexes have an important role in DNA repair. Recent mechanistic insight into the function and regulation of these universal chromosomal machines enables us to propose molecular models of chromosome structure, dynamics and function, illuminating one of the fundamental entities in biology.

In situ localization of DNA topoisomerase II, a major polypeptide component of the Drosophila nuclear matrix fraction

Abstract: DNA topoisomerase II has been immunochemically identified on protein blots as a major polypeptide component of the Drosophila nuclear matrix-pore complex-lamina fraction. Indirect immunofluorescence analyses of larval cryosections have confirmed the nuclear localization of topoisomerase II in situ. Although apparently excluded from the nucleolus, the topoisomerase protein is otherwise distributed throughout the interior of interphase nuclei. Similar immunocytochemical studies performed with permeabilized whole giant cells from third-instar larval salivary glands have shown topoisomerase II to be largely restricted to the polytene chromosomes. Upon nuclear disassembly during mitosis, the topoisomerase polypeptide appears to redistribute diffusely throughout the cell. Faint immunofluorescent staining of mitotic chromosomes is also observed.

Reptitive DNA sequences in drosophila.

Abstract: The satellite DNAs of Drosophila melanogaster and D. virilis have been examined by isopycnic centrifugation, thermal denaturation, and in situ molecular hybridization. The satellites melt over a narrow temperature range, reassociate rapidly after denaturation, and separate into strands of differing buoyant density in alkaline CsCl. In D. virilis and D. melanogaster the satellites constitute respectively 41% and 8% of the DNA isolated from diploid tissue. The satellites make up only a minute fraction of the DNA isolated from polytene tissue. Complementary RNA synthesized in vitro from the largest satellite of D. virilis hybridized to the centromeric heterochromatin of mitotic chromosomes, although binding to the Y chromosome was low. The same cRNA hybridized primarily to the α-heterochromatin in the chromocenter of salivary gland nuclei. The level of hybridization in diploid and polytene nuclei was similar, despite the great difference in total DNA content. The centrifugation and hybridization data imply that the α-heterochromatin either does not replicate or replicates only slightly during polytenization. Similar but less extensive data are presented for D. melanogaster. — In D. melanogaster cRNA synthesized from total DNA hybridized to the entire chromocenter (α- and β-heterochromatin) and less intensely to many bands on the chromosome arms. The X chromosome was more heavily labeled than the autosomes. In D. virilis the X chromosome showed a similar preferential binding of cRNA copied from main peak sequences.—It is concluded that the majority of repetitive sequences in D. virilis and D. melanogaster are located in the α- and β-heterochromatin. Repetitive sequences constitute only a small percentage of the euchromatin, but they are widely distributed in the chromosomes. During polytenization the α-heterochromatin probably does not replicate, but some or all of the repetitive sequences in the β-heterochromatin and the euchromatin do replicate.