Enzyme reaction rate studies in electromotor neurons of the weakly electric fish Apteronotus leptorhynchus

A histochemical analysis of reaction rates of a series of enzymes was performed in electromotor neurons of the weakly electric fish Apteronotus leptorhynchus. These neurons were selected because of their functional homogeneity. The high metabolic activity of these cells as well as their large size facilitate cytophotometric analysis in cryostat sections. Sections were incubated for the activity of hexokinase, glucose-6-phosphate dehydrogenase, succinate dehydrogenase, NADPH dehydrogenase, NADPH ferrihaemoprotein reductase and beta-hydroxybutyrate dehydrogenase. All media contained polyvinyl alcohol as tissue stabilizer and Nitro BT as final electron acceptor. Measurements were performed with a Vickers M85a cytophotometer. Linear relationships between the specific formation of formazan (test minus control reaction) and incubation time were obtained for all enzymes although some reactions showed an initial lag phase or an intercept with the ordinate. The relatively high activities of hexokinase, succinate dehydrogenase and the extremely low activity of hydroxybutyrate dehydrogenase indicate that energy is mainly supplied by glycolysis. Glucose-6-phosphate dehydrogenase showed a high activity whereas NADPH reductase and dehydrogenase activity were low in electromotor neurons, indicating that the NADPH generated is largely used for biosynthesis. Despite their synchronous firing pattern activity, electromotor neurons showed a considerable heterogeneity with respect to their metabolic activity.     

Pollenfertility and seed formation in theOrnithogalum umbellatum/angustifolium complex (Liliaceae/Scilloideae)

The pollen fertility and seed formation of six species of theOrnithogalum umbellatum/angustifolium complex and of seven related species were studied. Four types of pollen grains could be recognized. The pollen fertility varied greatly in this complex and is not related to the ploidy level. The seed formation ofO. umbellatum showed an adaptation to a subcontinental-Mediterranean climate, that ofO. angustifolium to an Atlantic climate. In both cases raindrops seem to be important for pollination, in view of the absence of insect pollinators. After open pollination 113 seedlings were obtained in four species. Their chromosome numbers were determined. Nearly all the cultivated seedlings were aneuploid, which points to a positive selection of euploids in nature, because aneuploid individuals are rare in the wild.Biosystematic Studies on theOrnithogalum umbellatum/angustifolium Complex III.—Previous parts of this series are Part I: Taxonomy. Proceeding Kon. Ned. Acad. Wet. series C,85 (4), 563–574 (1982) andvan Raamsdonk (1984).     

Intraspecific evolution ofMicroseris pygmaea (Asteraceae,Lactuceae) analyzed by cosegregation of phenotypic characters (QTLs) and molecular markers (RAPDs)

The Chilean annual,Microseris pygmaea, has differentiated in distinct coastal and inland series of populations after long-distance dispersal from western North America. Two plants from the most diverse biotypes were crossed, a large F₂ was raised and analysed for segregation of 30 phenotypic characters. Segregation of molecular markers (47 RAPDs, 1 RFLP, 2 isozymes) was determined in a subpopulation of 45 plants which include all extremes for the phenotypic characters. 32 marker/character cosegregations were significant at the 1% level in t-tests between dominant and homozygous recessive marker genotypes. Considering linkage among markers and pleiotropy of certain marker loci, the number of independent quantitative trait loci (QTLs) is reduced to about 18. Interactions among 2 or 3 QTLs affecting one character have been characterized. The phenotypic differentiation ofM. pygmaea during its evolution from a single founder individual begins to be understood at the level of single-gene mutants.     

Dorsoventral patterning of the mouse coat by Tbx15

Many members of the animal kingdom display coat or skin color differences along their dorsoventral axis. To determine the mechanisms that control regional differences in pigmentation, we have studied how a classical mouse mutation, droopy ear (de(H)), affects dorsoventral skin characteristics, especially those under control of the Agouti gene. Mice carrying the Agouti allele black-and-tan (a(t)) normally have a sharp boundary between dorsal black hair and yellow ventral hair; the de(H) mutation raises the pigmentation boundary, producing an apparent dorsal-to-ventral transformation. We identify a 216 kb deletion in de(H) that removes all but the first exon of the Tbx15 gene, whose embryonic expression in developing mesenchyme correlates with pigmentary and skeletal malformations observed in de(H)/de(H) animals. Construction of a targeted allele of Tbx15 confirmed that the de(H) phenotype was caused by Tbx15 loss of function. Early embryonic expression of Tbx15 in dorsal mesenchyme is complementary to Agouti expression in ventral mesenchyme; in the absence of Tbx15, expression of Agouti in both embryos and postnatal animals is displaced dorsally. Transplantation experiments demonstrate that positional identity of the skin with regard to dorsoventral pigmentation differences is acquired by E12.5, which is shortly after early embryonic expression of Tbx15. Fate-mapping studies show that the dorsoventral pigmentation boundary is not in register with a previously identified dermal cell lineage boundary, but rather with the limb dorsoventral boundary. Embryonic expression of Tbx15 in dorsolateral mesenchyme provides an instructional cue required to establish the future positional identity of dorsal dermis. These findings represent a novel role for T-box gene action in embryonic development, identify a previously unappreciated aspect of dorsoventral patterning that is widely represented in furred mammals, and provide insight into the mechanisms that underlie region-specific differences in body morphology.     

Decreased Energy Metabolism Extends Life Span in Caenorhabditis elegans Without Reducing Oxidative Damage

On the basis of the free radical and rate of living theories of aging, it has been proposed that decreased metabolism leads to increased longevity through a decreased production of reactive oxygen species (ROS). In this article, we examine the relationship between mitochondrial energy metabolism and life span by using the Clk mutants in Caenorhabditis elegans. Clk mutants are characterized by slow physiologic rates, delayed development, and increased life span. This phenotype suggests that increased life span may be achieved by decreasing energy expenditure. To test this hypothesis, we identified six novel Clk mutants in a screen for worms that have slow defecation and slow development and that can be maternally rescued. Interestingly, all 11 Clk mutants have increased life span despite the fact that slow physiologic rates were used as the only screening criterion. Although mitochondrial function is decreased in the Clk mutants, ATP levels are normal or increased, suggesting decreased energy utilization. To determine whether the longevity of the Clk mutants results from decreased production of ROS, we examined sensitivity to oxidative stress and oxidative damage. We found no evidence for systematically increased resistance to oxidative stress or decreased oxidative damage in the Clk mutants despite normal or elevated levels of superoxide dismutases. Overall, our findings suggest that decreased energy metabolism can lead to increased life span without decreased production of ROS.MUTATIONS in clk-1 have been shown to increase longevity in both worms and mice, suggesting that these mutations affect an evolutionarily conserved mechanism of life span extension (Lakowski and Hekimi 1996; Liu et al. 2005; Lapointe et al. 2009). The CLK-1 protein encodes a hydroxylase involved in the synthesis of ubiquinone (Ewbank et al. 1997), a multifunctional, lipid-like molecule that transfers electrons in the electron transport chain and may also act as an intracellular antioxidant (Maroz et al. 2009). clk-1 was originally identified in worms in a screen for maternally rescued mutations that result in abnormal development and behavior. In addition to slow development and slow defecation, clk-1 mutants show decreased brood size, a decreased rate of thrashing, and a decreased rate of pharyngeal pumping (Wong et al. 1995). It was a surprise, however, that clk-1 worms also displayed extended longevity, because, at the time that it was discovered, only two other mutants, age-1 and daf-2, with very different phenotypes, had been found to extend longevity (Friedman and Johnson 1988; Kenyon et al. 1993).It is currently uncertain how mutations in clk-1 result in the overall slowing of development and physiologic rates as well as an extended life span. One classic theory of aging, called the rate of living theory, postulates the existence of a link between energy metabolism and aging (Pearl 1922; Speakman 2005). This theory proposes that what determines the life span of an organism is the rate at which it produces and uses energy at the cellular level. Thus, the fact that clk-1 worms exhibit slow physiologic rates and development suggests a decrease in the rate that these worms utilize energy, and, by the rate of living theory, this could account for their long life span.In support of the rate of living theory, the loss of clk-1 has been shown to result in decreased whole-worm oxygen consumption (Felkai et al. 1999; Yang et al. 2007) and decreased electron transfer from complex I to complex III in the electron transport chain (Kayser et al. 2004b), although this has not been observed by all investigators (Miyadera et al. 2001). While some reports have suggested that energy consumption is not reduced in clk-1 worms, at least under liquid culture conditions (Braeckman et al. 2002), the observation that clk-1 worms have higher levels of ATP than wild-type worms (Braeckman et al. 1999) suggests a decreased use of energy in clk-1 worms regardless of whether energy production is normal or decreased. It has also been found that clk-1 double-mutant combinations that exhibit slower development than clk-1 worms live even longer than clk-1 worms (Lakowski and Hekimi 1996). In addition, overexpression of clk-1 prevents the slowing of the defecation rate with age, increases mitochondrial function, and decreases life span (Felkai et al. 1999).Drawing on ideas from the free radical theory of aging (Harman 1956), it has been suggested that a possible mechanism underlying the rate of living theory is that decreased metabolism results in a lower rate of production of reactive oxygen species (ROS). As the free radical theory of aging proposes that aging results from the accumulation of molecular damage caused by ROS, then lower ROS production should result in slower aging. In clk-1 worms, it has not been possible to directly measure levels of ROS in vivo; however, measurement of hydrogen peroxide production from submitochondrial particles has demonstrated increased ROS generation in clk-1 mitochondria compared to wild type (Yang et al. 2009). In addition, the superoxide production potential is increased in clk-1 worms compared to wild-type N2 worms (Braeckman et al. 2002). Despite showing increased levels of ROS production, clk-1 worms have been found to have normal or decreased levels of oxidative damage (Kayser et al. 2004a; Yang et al. 2007, 2009) and decreased accumulation of lipofuscin (Braeckman et al. 2002). The decrease in oxidative damage that occurs in spite of increased ROS production likely results from increased antioxidant defenses. In support of this conclusion, sod-2 and sod-3 mRNA are increased in clk-1 worms compared to wild type (Yang et al. 2007).Clearly, the levels of ROS production and antioxidant defense are altered in clk-1 worms and likely contribute to the physiology and life span of these worms. Evidence supporting a role for altered ROS levels in determining the clk-1 phenotype comes from the demonstration that increasing the levels of ROS through decreasing superoxide dismutase expression has been shown to modulate a variety of phenotypes in clk-1 worms (Shibata et al. 2003; Yang et al. 2007). It is important to note, however, that the decrease in oxidative damage in clk-1 worms appears not to contribute to their long life as it is possible to experimentally increase oxidative damage in clk-1 worms beyond wild-type levels without reducing life span (Yang et al. 2007).In addition to clk-1, four other genes have been identified that yield a clk-1-like phenotype (Clk phenotype), which includes slow development, slow defecation, slow pharyngeal pumping, decreased brood size and long life span coupled with maternal rescue (homozygous mutants from heterozygous mothers are phenotypically normal) (Hekimi et al. 1995; Lemieux et al. 2001). The Clk phenotype has been studied in most detail in clk-1 worms (Wong et al. 1995) and, subsequently, with gro-1 (Lemieux et al. 2001), clk-2 (Benard et al. 2001), and tpk-1 worms (de Jong et al. 2004), while clk-3 worms have not been extensively studied [although clk-3 worm energy metabolism and oxygen consumption have been examined (Braeckman et al. 2002; Shoyama et al. 2009)]. Despite the phenotypic similarity of these mutants, the mutations that have been identified thus far have been shown to occur in genes encoding proteins with a wide range of functions with no obvious relationship to one another. gro-1 encodes a tRNA-modifying enzyme (Lemieux et al. 2001), clk-2 encodes a homolog of yeast Tel2p and a regulator of several PI3K-related protein kinases (Ahmed et al. 2001; Benard et al. 2001; Jiang et al. 2003; Takai et al. 2007), and tpk-1 encodes thiamine pyrophosphokinase, which is necessary for the assimilation of thiamine (vitamin B1) (de Jong et al. 2004).All of the Clk mutants that have been identified exhibit slow physiologic rates and increased life span, suggesting that one may be sufficient for the other. To test this hypothesis, we identified six novel Clk mutants and demonstrate that these strains bear all of the characteristic features of the Clk phenotype, including extended longevity. We further show that mitochondrial function is decreased in the Clk mutants but that this decrease does not result in increased resistance to oxidative stress or decreased oxidative damage. Our results provide a plausible explanation for the extended life span observed in the Clk mutants and support aspects of the rate of living theory of aging while casting further doubt on the free radical theory of aging.