Mitochondrial genome in animal cells. Structure, organization, and evolution

In the past decade, the development of new DNA, RNA, and protein technologies has greatly incremented the knowledge about the organization and expression of mitochondrial DNA. The complete base sequence of mitochondrial DNA of several animals is known and many data are rapidly accumulating on the mitochondrial genomes of other systems. Here we discuss the results so far obtained that disclosed unexpected features of mitochondrial genetics. Furthermore, mitochondrial DNA has become established as a powerful tool for evolutionary studies in animals. Evidences are presented demonstrating that the evolution of mitochondrial DNA has proceeded in different ways in the various taxonomic groups. Data on heteroplasmic animals, which demonstrate the rapid evolution of mitochondrial DNA, are also presented.     

Localization of the gene for a third G protein β-subunit to mouse chromosome 6 near Raf-1

The large family of signal transducing proteins known as G proteins are heterotrimers that dissociate into an independent α-subunit and βγ-subunit complex after ligand binding or other stimulation. For Gα, at least 30 distinct sequences representing 10 different classes have been identified. On the other hand, cDNAs for only three Gβ-subunit genes have been isolated so far. All three of the Gβ genes have been chromosomally mapped in the human, but only two in the mouse. Using a human retinal cDNA for the third G protein β-subunit, we have mapped the corresponding gene, termed Gnb-3, to mouse Chromosome 6 with somatic cell hybrids and have positioned it distal to but near the marker Raf-1 by analysis of the progeny of three genetic crosses.     

Temperature-related divergence in experimental populations of Drosophila melanogaster. II. Correlation between fitness and body dimensions

From a laboratory stock of Drosophila melanogaster (Oregon), reared for more than 20 years at 18° C, a new population was derived and maintained at 28° C for 8 years. The chromosomal and cytoplasmic contribution to genetic divergence between the two populations was estimated. Six body traits and reproductive fitness were taken into account. The third chromosome is responsible for the adaptive difference for temperature between the two lines. Temperature-selected genes which control body size are located on the second and third chromosomes, although the contribution of each chromosome depends on the environment in which the flies develop. The correlation between the chromosomal and cytoplasmic contributions to different traits and fitness, changes with temperature. At 28° C the correlation between fitness and each body trait is proportional to the response to selection exhibited by each of them, but this is not true at 18° C. Body size has, therefore, an adaptive significance in relation to temperature, which is expressed only in the environment where selection occurs. Cytoplasmic genes affect almost all characters to an extent similar to that of chromosomal genes. Inter-chromosomal and nucleo-cytoplasmic interactions are present and also change with temperature. In general, genes selected in a given environment produce greater phenotypic changes in that environment than in another. The population that experienced both temperatures is fitter in both environments, suggesting that the capacity to adapt to warm temperatures depends on genes other than those which are involved in the adaptation to cold.     

Trisomy 21 mosaicism in two subjects from two generations.

In the course of a chromosome fragility investigation on the cancer prone hereditary disorder xeroderma pigmentosum, a low proportion of cells with a 47,XY,+21 karyotype was found in lymphocyte cultures of a patient not showing any Down syndrome symptom. The presence of trisomy 21 mosaicism was demonstrated also in peripheral blood of the healthy father and confirmed by "chromosome painting" that allowed a rapid detection of chromosomes 21 on metaphase cells and interphase nuclei. The trisomic cell line was not detected in fibroblast cultures. The analysis of chromosome 21 heteromorphism indicated that in both subjects the mosaic could result from either a diploid or an aneuploid zygote. Since in the trisomic cell line of the father and the son the extra chromosome 21 seems to be the same, a predisposition toward mitotic errors (non-disjunction or anaphase lagging) may be postulated, leading to the recurrent gain or loss of a specific chromosome 21. In order to test the hypothesis of an abnormal mitotic behaviour of the chromosome 21, we investigated the centromere separation index and the DNA restriction pattern in Southern blots probed with satellite DNA sequences specific for chromosome 21 centromere. Both the approaches did not reveal any peculiar feature that may account for the genetically determined proneness to mitotic error observed in the family.     

An Ultrastructural Investigation on Vitellophage Invasion of the Yolk Mass during and after Germ Band Formation in Embryos of the Stick Insect Carausius morosus Br.

Developing embryos of the stick insect Carausius morosus were examined ultrastructurally with a view to studying vitellophage invasion of the yolk mass during and after germ band formation. Newly laid eggs in C.morosus have a unique yolk fluid compartment surrounded by a narrow fringe of cytoplasm comprising several small yolk granules. Vitellophages originate mainly from a thin layer of stem cells, the so-called yolk cell membrane, interposed between the germ band and the yolk mass. Throughout development, a thin basal lamina separates the yolk cell membrane from the overlying embryo.
Vitellophages extend from the yolk cell membrane with long cytoplasmic processes or filopodia to invade the central yolk mass. Along their route of entrance, filopodia engulf portions of the yolk mass and sequester it into membrane-bounded granules. As this process continues, the yolk mass is gradually partitioned into a number of yolk granules inside the vitellophages.
Later in development, the yolk cell membrane is gradually replaced by the endodermal cells that emerge from the anterior and posterior embryonic rudiments. From this stage of development onwards, vitellophages remain attached to the basal lamina through long filopodia extending between the endodermal cells. Yolk confined in different vitellophagic cells appears heterogeneous both in density and texture, suggesting that yolk degradation may be spatially differentiated.     

Phenotypic and cytotoxic characteristics of the immune cells of the human placenta

Despite some functional impairment of the newborn's T-cell immune system, most infants survive the intrauterine and perinatal period without succumbing to infection or maternal lymphocyte engraftment. The placenta may play a crucial role in protecting the infant from microbial and histocompatibility antigens. Accordingly, we studied phenotypic and functional capacities of placental cells. Placentas were obtained from uncomplicated pregnancies. Matched cord blood and maternal peripheral blood were also obtained in many instances. Fresh minced placental tissue was washed and digested with collagenase and DNase and mononuclear cells were obtained by density gradient centrifugation. The average yield was 10(6) cells/g of tissue with greater than 80% viability. Chromosome analysis of five placental preparations indicated that these cells were of fetal rather than maternal origin. The isolated placental cells consisted of trophoblasts, lymphocytes (74 +/- 3%), monocytes (16 +/- 3%), and granulocytes (8 +/- 2%). E-rosette forming cells (T cells) made up 65 +/- 2% and surface membrane immunoglobulin positive cells made up 8 +/- 1% of the placental mononuclear cells. Fluorescent activated analysis of the mononuclear cells indicated less Leu 4-positive cells (Pan-T) 43 +/- 3%, and less Leu 3-positive (T-helper cells) (25 +/- 2%), than cord and maternal cell preparations. Leu-2, DR, and B1 positive cells were similar to those in cord and maternal blood. Leu 7 and especially Leu 11 positive cells, markers for natural killer cells, were abundant in placental cells, making up 4 +/- 0.7% and 20 +/- 3%, respectively. The Leu 7/Leu 11 ratio of the placental cells was different from either the maternal or cord blood cells. Natural killer activity of placental cells against a K562 natural killer target was low, despite the abundance of cells with NK markers. The K562 activity was low in the placental cells, similar to the low NK activity of maternal and cord cells. Molt 4f killer activity was near normal. Lectin-dependent cytotoxicity using an EL-4 cell target plus PHA was low in placentas, compared to normal, maternal, or cord cell cytotoxicity. Matched samples indicated that LDCC activity was mother greater than cord greater than placenta. Antibody-dependent cytotoxicity (Raji target) of placental cells showed low activity, and again the paired studies indicated that normal controls greater than maternal greater than cord greater than placenta cytotoxicity.(ABSTRACT TRUNCATED AT 400 WORDS)