Changes in photoreceptor currents and their sensitivity to the chemoeffector tryptone during gamete mating in<Emphasis Type="Italic"> Chlamydomonas reinhardtii</Emphasis>

Chlamydomonas reinhardtii Dangeard generates photoreceptor currents (PCs) upon light excitation. These currents play a key role in the signal transduction chain for photomotility responses. We have previously found that inhibition of PCs by tryptone occurs only in gametes that display chemotaxis toward this agent, and is not observed in chemotactically insensitive vegetative cells. Here we show that the sensitivity to tryptone is characteristic of gametes of both mating types, and examine the influence of gamete mating on PCs and their sensitivity to tryptone. The amplitude of PCs increases after cell fusion, but the sensitivity of these currents to tryptone decreases upon flagellar adhesion and/or an increase in the intracellular cAMP concentration. Net chemotaxis toward tryptone is reduced in young zygotes compared to gametes. We conclude that gamete mating leads to rapid inactivation of a gamete-specific chemosensory system.     

Development of tolerance against toxic cyanobacteria in Daphnia

We tested whether previous exposure to a toxic strain of cyanobacteria (Microcystis) affects survival, growth, and reproduction of a common herbivore, Daphnia magna. Samples from three natural populations of D. magna were each divided into two parts; one part was fed a mixture of toxic Microcystis and the non-toxic green alga Scenedesmus whereas the other part was fed only Scenedesmus. After four weeks, we compared the ability of these two populations to withstand the toxic Microcystis by assessing survivorship, growth, and reproduction. We found that the ability of D. magna to cope successfully with toxic Microcystis is improved if the animals have experienced previous exposure to toxic Microcystis. This suggests that the toxin may less affect the D. magna populations that are repeatedly exposed to toxic cyanobacteria in their natural habitat than populations lacking prior exposure. Since the ability to tolerate toxins is manifested in both improved survival and larger size of the animals, it may have considerable impact on zooplankton community composition in fresh-waters.     

dFatp regulates nutrient distribution and long‐term physiology in Drosophila

Nutrient allocation and usage plays an important part in regulating the onset and progression of age‐related functional declines. Here, we describe a heterozygous mutation in Drosophila (dFatp) that alters nutrient distribution and multiple aspects of physiology. dFatp mutants have increased lifespan and stress resistance, altered feeding behavior and fat storage, and increased mobility. Concurrently, mutants experience impairment of cardiac function. We show that endurance exercise reverses increased lipid storage in the myocardium and the deleterious cardiac function conferred by dFatp mutation. These findings establish a novel conserved genetic target for regulating lifespan and physiology in aging animals. These findings also highlight the importance of varying exercise conditions in assessing aging functions of model organisms.     

Overexpression of<Emphasis Type="Italic">Arabidopsis</Emphasis> phytochelatin synthase (<Emphasis Type="Italic">atpcsi</Emphasis>) does not change the maximum capacity for non-protein thiol production induced by Cadmium

Phytochelatins (PCs) play an important role in heavy-metal homeostasis and detoxification. However, we previously reported that the overexpression of PC synthase inArabidopsis does not lead to increased tolerance of cadmium but, rather, plants show higher Cd sensitivity. Here, we compared the maximum capacity for non-protein thiol (NPT) production at various concentrations of Cd in order to estimate PC synthesis indirectly for both transgenic (pcs9) and wild-type plants. The pcs9 line produced the highest level of NPT when treated with 200 p.M Cd for 3 d. In comparison, the maximum productivity by the wild type was in response to 500 μM Cd. Nevertheless, the absolute amounts of NPT produced did not differ significantly between those two genotypes. Furthermore, exogenous application of 1 mM GSH did not dramatically change the capacity for either pcs9 or wild-type plants. These results suggest that Cd hypersensitivity in the transgenic pcs9 may not be caused by supraoptimal intracellular concentrations of PC, but may, instead, be due to overexpressed PC synthase itself because that enzyme can bind metals. This action, therefore, may lead to some unknown disruption in cellular metal homeostasis under Cd stress.     

Limitations of RNAi of α6 nicotinic acetylcholine receptor subunits for assessing the in vivo sensitivity to spinosad

Abstract Spinosad is a widely used insecticide that exerts its toxic effect primarily through interactions with the nicotinic acetylcholine receptor. The α6 nicotinic acetylcholine receptor subunit is involved in spinosad toxicity as demonstrated by the high levels of resistance observed in strains lacking α6. RNAi was performed against the Dα6 nicotinic acetylcholine receptor subunit in Drosophila melanogaster using the Gal4‐UAS system to examine if RNAi would yield results similar to those of Dα6 null mutants. These Dα6‐deficient flies were subject to spinosad contact bioassays to evaluate the role of the Dα6 nicotinic acetylcholine receptor subunit on spinosad sensitivity. The expression of Dα6 was reduced 60%–75% as verified by quantitative polymerase chain reaction. However, there was no change in spinosad sensitivity in D. melanogaster. We repeated RNAi experiments in Tribolium castaneum using injection of dsRNA for Tcasα6. RNAi of Tcasα6 did not result in changes in spinosad sensitivity, similar to results obtained with D. melanogaster. The lack of change in spinosad sensitivity in both D. melanogaster and T. castaneum using two routes of dsRNA administration shows that RNAi may not provide adequate conditions to study the role of nicotinic acetylcholine receptor subunits on insecticide sensitivity due to the inability to completely eliminate expression of the α6 subunit in both species. Potential causes for the lack of change in spinosad sensitivity are discussed.     

Variation in adult life history and stress resistance across five species of<Emphasis Type="Italic">Drosophila</Emphasis>

Dry weight at eclosion, adult lifespan, lifetime fecundity, lipid and carbohydrate content at eclosion, and starvation and desiccation resistance at eclosion were assayed on a long-term laboratory population ofDrosophila melanogaster, and one recently wild-caught population each of four other species ofDrosophila, two from themelanogaster and two from theimmigrans species group. The relationships among trait means across the five species did not conform to expectations based on correlations among these traits inferred from selection studies onD. melanogaster. In particular, the expected positive relationships between fecundity and size/lipid content, lipid content and starvation resistance, carbohydrate (glycogen) content and desiccation resistance, and the expected negative relationship between lifespan and fecundity were not observed. Most traits were strongly positively correlated between sexes across species, except for fractional lipid content and starvation resistance per microgram lipid. For most traits, there was evidence for significant sexual dimorphism but the degree of dimorphism did not vary across species except in the case of adult lifespan, starvation resistance per microgram lipid, and desiccation resistance per microgram carbohydrate. Overall,D. nasuta nasuta andD. sulfurigaster neonasuta (immigrans group) were heavier at eclosion than themelanogaster group species, and tended to have somewhat higher absolute lipid content and starvation resistance. Yet, these twoimmigrans group species were shorter-lived and had lower average daily fecundity than themelanogaster group species. The smallest species,D. malerkotliana (melanogaster group), had relatively high daily fecundity, intermediate lifespan and high fractional lipid content, especially in females.D. ananassae (melanogaster group) had the highest absolute and fractional carbohydrate content, but its desiccation resistance per microgram carbohydrate was the lowest among the five species. In terms of overall performance, the laboratory population ofD. melanogaster was clearly superior, under laboratory conditions, to the other four species if adult lifespan, lifetime fecundity, average daily fecundity, and absolute starvation and desiccation resistance are considered. This finding is contrary to several recent reports of substantially higher adult lifespan and stress resistance in recently wild-caught flies, relative to flies maintained for a long time in discretegeneration laboratory cultures. Possible explanations for these apparent anomalies are discussed in the context of the differing selection pressures likely to be experienced byDrosophila populations in laboratory versus wild environments. This paper is dedicated to the memory of our friend and former colleague Dr Hans Raj Negi, who tragically passed away at a very young age in a road accident in November 2003.     

Detection of triclosan using 2-domain hemoglobin promoter of Daphnia magna

Triclosan has been widely used as an antimicrobial agent. However, triclosan was found to cause toxicity, including muscle contraction disturbances, carcinogenesis, and endocrine disorders. In addition, it was found to affect central nervous system function adversely and even have ototoxic effects. Conventional methods for detecting such triclosan can be performed easily. However, the conventional detection methods are inadequate in precisely reflecting the impact of toxic substances on stressed organisms. Therefore, a test model for the toxic environment at the molecular level through the organism is needed. From that point of view, Daphnia magna is being used as a ubiquitous model. D. magna has the advantages of easy cultivation, a short lifespan and high reproductive capacity, and high sensitivity to chemicals. Therefore, the protein expression pattern of D. magna that appear in response to chemicals can be utilized as biomarkers for detecting specific chemicals. In this study, we characterized the proteomic response of D. magna following triclosan exposure via two-dimensional (2D) gel electrophoresis. As a result, we confirmed that triclosan exposure completely suppressed D. magna 2-domain hemoglobin protein and evaluated this protein as a biomarker for triclosan detection. We constructed the HeLa cells in which the GFP gene was controlled by D. magna 2-domain hemoglobin promoter, which under normal conditions, expressed GFP, but upon triclosan exposure, suppressed GFP expression. Consequently, we consider that the HeLa cells containing the pBABE-HBF3-GFP plasmid developed in this study can be used as novel biomarkers for triclosan detection.     

drr‐2 encodes an eIF4H that acts downstream of TOR in diet‐restriction‐induced longevity of C. elegans

Dietary restriction (DR) results in a robust increase in lifespan while maintaining the physiology of much younger animals in a wide range of species. Here, we examine the role of drr‐2, a DR‐responsive gene recently identified, in determining the longevity of Caenorhabditis elegans. Inhibition of drr‐2 has been shown to increase longevity. However, the molecular mechanisms by which drr‐2 influences longevity remain unknown. We report here that drr‐2 encodes an ortholog of human eukaryotic translation initiation factor 4H (eIF4H), whose function is to mediate the initiation step of mRNA translation. The molecular function of DRR‐2 is validated by the association of DRR‐2 with polysomes and by the decreased rate of protein synthesis observed in drr‐2 knockdown animals. Previous studies have also suggested that DR might trigger a regulated reduction in drr‐2 expression to initiate its longevity response. By examining the effect of increasing drr‐2 expression on DR animals, we find that drr‐2 is essential for a large portion of the longevity response to DR. The nutrient‐sensing target of rapamycin (TOR) pathway has been shown to mediate the longevity effects of DR in C. elegans. Results from our genetic analyses suggest that eIF4H/DRR‐2 functions downstream of TOR, but in parallel to the S6K/PHA‐4 pathway to mediate the lifespan effects of DR. Together, our findings reveal an important role for eIF4H/drr‐2 in the TOR‐mediated longevity responses to DR.     

A simple chromosomal marker can reliably distinguishes <Emphasis Type="Italic">Poncirus</Emphasis> from <Emphasis Type="Italic">Citrus</Emphasis> species

Several chromosome types have been recognized in Citrus and related genera by chromomycin A₃ (CMA) banding patterns and fluorescent in situ hybridization (FISH). They can be used to characterize cultivars and species or as markers in hybridization and backcrossing experiments. In the present work, characterization of six cultivars of P. trifoliata (“Barnes”, “Fawcett”, “Flying Dragon”, “Pomeroy”, “Rubidoux”, “USDA”) and one P. trifoliata × C. limonia hybrid was performed by sequential analyses of CMA banding and FISH using 5S and 45S rDNA as probes. All six cultivars showed a similar CMA⁺ banding pattern with the karyotype formula 4B + 8D + 6F. The capital letters indicate chromosomal types: B, a chromosome with one telomeric and one proximal band; D, with only one telomeric band; F, without bands. In situ hybridization labeling was also similar among cultivars. Three chromosome pairs displayed a closely linked set of 5S and 45S rDNA sites, two of them co-located with the proximal band of the B type chromosomes (B/5S-45S) and the third one co-located with the terminal band of a D pair (D/5S-45S). The B/5S-45S chromosome has never been found in any citrus accessions investigated so far. Therefore, this B chromosome can be used as a marker to recognize the intergeneric Poncirus × Citrus hybrids. The intergeneric hybrid analyzed here displayed the karyotype formula 4B + 8D + 6F, with two chromosome types B/5S-45S and two D/5S-45S. The karyotype formula and the presence of two B/5S-45S chromosomes clearly indicate that the plant investigated is a symmetric hybrid. It also demonstrates the suitability of karyotype analyses to differentiate zygotic embryos or somatic cell fusions involving trifoliate orange germplasm. During the submission of this paper, we analyzed 25 other citrus cultivars with the same methodology and we found that the chromosome marker reported here can indeed distinguish Poncirus trifoliata from grapefruits, pummelos, and one variegated access of Citrus, besides the previously reported access of limes, limons, citrons, and sweet-oranges. However, among 14 mandarin cultivars, two of them displayed a single B/5S-45S chromosome, whereas in Citrus hystrix D.C., a far related species belonging to the Papeda subgenus, this chromosome type was found in homozygosis. Since these two mandarin cultivars are probably of hybrid origin, we assume that for almost all commercial cultivars and species of the subgenus Citrus this B type chromosome is a useful genetic marker.     

The fine structure and cytology of the association between the parasitic red algaHolmsella australis and its red algal hostGracilaria furcellata

Summary Holmsella australis Noble andKraft ms. is a colourless red algal parasite, forming whitish pustules on its photosynthetic red algal host,Gracilaria furcellata Harvey. In the infected region, host cortical tissue continues to grow and enclose the expanding pustule. Filaments of both host and parasite grow apically, the cells being connected by primary pit connections (PCs). Secondary PCs form between cells of the same species, and in addition,H. australis initiates the formation of secondary PCs with cells ofG. furcellata. All three types of secondary PC are morphologically distinct. In hostparasite PCs the surface adjoining the host cell is similar in structure to a host-host PC, while that adjoining the parasite cell has the structure of a parasite-parasite PC. The plasma membrane is continuous between the cells of the unrelated host and parasite. In addition, a cap membrane is typically produced only on the host surface, though occasionally the parasite side is enclosed by a cap membrane as well. Cap membranes are absent from parasite-parasite PCs (making them intracellular), while host-host PCs are typically extracellular, both cells producing cap membranes. The presence or absence of a cap membrane in certain positions appears to vary, and suggests that cells may be able to regulate its presence. Since transport of nutrients would be expected to occur from host to parasite cells, and between parasite cells, the morphological evidence presented here suggests the PCs may be the pathway.     

<Emphasis Type="Italic">Drosophila</Emphasis> Bys is nuclear and shows dynamic tissue-specific expression during development

Although the bys-like family of genes has been conserved from yeast to humans, it is not apparent to what extent the function of Bys-like proteins has been conserved across phylogenetic groups. Human Bystin is thought to function in a novel cell adhesion complex involved in embryo implantation. The product of the yeast bys-like gene, Enp1, is nuclear and has a role in pre-ribosomal RNA (pre-rRNA) splicing and ribosome biogenesis. To gain insight into the function of the Drosophila melanogaster bys-like family member, termed bys, we examined bys mRNA expression and the localization of Bys protein. In embryos, bys mRNA is expressed in a tissue-specific pattern during gastrulation. In the larval wing imaginal disc, bys mRNA is expressed in the ventral and dorsal regions of the wing pouch, regions that give rise to epithelia that adhere to one another after the wing disc everts. The bys mRNA expression patterns could be interpreted as being consistent with a role for Bys in events requiring cell-cell interactions. However, embryonic bys mRNA expression patterns mirror those of genes that are potential targets of the growth regulator Myc and encode nucleolar proteins implicated in cell growth. Additionally, in Schneider line 2 (S2) cells, an epitope-tagged Bys protein is localized to the nucleus, suggesting that Drosophila Bys function may be conserved with that of yeast Enp1.Edited by D.A. Weisblat     

Prohormone convertases 1/3, 2, furin and protein 7B2 (Secretogranin V) in endocrine cells of the human pancreas

Prohormone convertases (PCs) are proteinases that cleave inactive prohormones to biologically active peptides. Seven PCs have been identified; two of them, PC1/3 and PC2, have only been localized in neuroendocrine (NE) tissues; a third, furin, in both endocrine and exocrine tissues. We have studied the immunoreactivity of PC1/3, PC2 and furin in the four major NE cell types of the human pancreas by using double immunofluorescence techniques. The study also included the expression of NE secretory protein 7B2 (secretogranin V), a member of the granin family, which influences the function of PC2. The results showed that the three PCs and 7B2 were expressed only in endocrine pancreas, furin also in exocrine cells. Insulin (B) cells harboured PC1/3 and PC2, but not furin. Glucagon (A) cells were immunoreactive to all three PCs; all glucagon cells expressed PC2, but one subpopulation showed PC1/3 immunoreactivity and another furin. Only a few somatostatin (D) cells contained PC2, but no other proconvertase. Pancreatic polypeptide (PP) cells were non-reactive to all three PCs. 7B2 occurred only in insulin and glucagon cells. A varying co-localization pattern was observed between PCs and between PCs and 7B2, with the exception of PC1/3 and furin which were not co-localized. In conclusion, our study shows that PCs are localized in insulin and glucagon cells and do seem to be important in these cell types for processing of hormone and other protein precursors, especially chromogranins, but for the two other major cell types probably other enzymes are of importance.     

Insulin‐like signalling in neurons controls lifespan in C. elegans

Insulin‐like signalling controls C. elegans lifespan, development and metabolism. Mutations that weaken this insulin‐like signalling pathway extend lifespan. Severe mutations abolishing insulin‐like signalling cause animals to arrest development as dauer larvae, a larval form specialized for stress resistance and long‐term survival. A number of the genes acting in this pathway have been cloned, including daf‐2, which encodes a homolog of vertebrate insulin/IGF‐I receptors, and age‐1, encoding the C. elegans homolog of the PI(3)K p110 catalytic subunit. In order to identify cells from which insulin‐like signalling controls lifespan and development, transgenic animals were constructed which possessed insulin‐like signalling only in specific cell types. To achieve this, cell‐type specific promoters were used to drive expression of daf‐2 or age‐1 cDNAs in daf‐2(–/–) or age‐1(–/–) backgrounds, respectively. By utilizing this strategy, we could restore wild‐type daf‐2 or age‐1 activity only in cells that are capable of expressing each transgene. Restoring insulin‐like signalling to the nervous system of daf‐2 or age‐1 mutants could rescue long lifespan. This result was specific for transgenes restoring insulin‐like signalling to the nervous system. Expressing daf‐2 or age‐1 cDNAs from muscle‐ or intestinally‐restricted promoters was insufficient to rescue lifespan. In contrast, age‐1 and daf‐2 expression in either neuronal or non‐neuronal cell types rescued dauer larval arrest in the mutants. These findings demonstrate that insulin‐like signalling pathways in the nervous system control C. elegans lifespan.     

The auxin response of actin is altered in the rice mutantYin-Yang

Summary The rice mutantYin-Yang has been selected during a screen for resistance to cytoskeletal drugs and is characterized by alterations in epidermal cell length and a precocious onset of gravitropism. The elongation response of coleoptile segments to auxin does not reveal changes of auxin sensitivity inYin-Yang. However, in contrast to the wild type, cell elongation inYin-Yang is highly sensitive to the actin-polymerisation blocker cytochalasin D. This increased sensitivity to cytochalasin D requires optimal concentrations of auxin to become manifest. The auxin response of actin microfilaments in epidermal cells differs between wild type and mutant. In the wild type, the longitudinal microfilament bundles become loosened in response to auxin. In the mutant, these bundles disintegrate partially and are replaced by a network of short filaments surrounding the nucleus. Several aspects of the mutant phenotype can be mimicked in the wild type by treatment with cytochalasin D. The mutant phenotype is discussed in terms of signal-dependent changes of actin dynamics and the putative role of actin during cell elongation.Abbreviations CD cytochalasin D - EPC ethyl-N-phenylcarbamate     

The <Emphasis Type="Italic">Thlaspi caerulescens</Emphasis> NRAMP Homologue TcNRAMP3 is Capable of Divalent Cation Transport

The NRAMP gene family encodes integral membrane protein and mediates the transport of Fe, however, its function in transport of toxic metal ions is not very clear in plants. TcNRAMP3 was isolated from Thlaspi caerulescens, and encoded a metal transporter member of the NRAMP family. TcNRAMP3 was predominantly expressed in roots of T. caerulescens by semi-quantitative RT-PCR. The expression of TcNRAMP3 was induced by iron starvation and by the heavy metals Cd and Ni in roots. TcNRAMP3 was able to rescue growth of an iron uptake fet3fet4 mutant yeast strain, suggesting a possible role in iron transport. Expression of TcNRAMP3 in yeast increased Cd sensitivity and Cd content, while it enhanced the Ni resistance and reduced Ni accumulation, indicating that TcNRAMP3 could accumulate Cd and exclude Ni in yeast. Furthermore, overexpression of TcNRAMP3 in tobacco resulted in slight Cd sensitivity of root growth and did not influence Ni resistance. These results suggested that TcNRAMP3 played a role in metal cation homeostasis in plant.     

Glutathione-mediated Antioxidative Mechanisms in Sunflower (<Emphasis Type="Italic">Helianthus Annuus</Emphasis> L.) Cells in Response to Cadmium Stress

Cadmium (Cd) homeostasis and detoxification in sunflower (Helianthus annuus L.) cells differing in Cd sensitivity/tolerance were studied by analyzing the glutathione-mediated antioxidant mechanism vis-à-vis phytochelatin biosynthesis in vitro. Calluses exposed to Cd-shock/-acclimatization (150μM) were assayed for oxidative stress, reduced glutathione (GSH), glutathione disulfide (GSSG), phytochelatins (PCs) and reactive oxygen species (ROS). Although Cd did not induce any oxidative stress in Cd-tolerant callus (TCd), it generated oxidative stress in Cd-shock callus (SCd) both in terms of lipid peroxidation and protein oxidation. GSH/GSSG ratio remained similar to control values in the cadmium-acclimatized calluses. However, after acute treatment, there was a decline in both GSH and GSSG levels in SCd with concomitant reduction in the GSH/GSSG ratio. Analysis of PCs was performed using HPLC and mass spectrometry methods. PC concentration in TCd were approximately twice those that in SCd, showing in both cases a 1:2:1 relative proportion for PC n = 2 (PC2): PC n = 3 (PC3): PC n = 4 (PC4). Calluses growing in the presence of Cd developed an increased resistance to paraquat oxidative stress generation. These results indicated that PCs synthesis was an important mechanism for Cd detoxification in sunflower calluses, but the capacity to grow in the presence of Cd is related to the tissues ability to maintain high intracellular levels of GSH.     

Hexokinase-mitochondrial interaction in cardiac tissue: implications for cardiac glucose uptake,the <Superscript>18</Superscript>FDG lumped constant and cardiac protection

The hexokinases are fundamental regulators of cardiac glucose uptake; by phosphorylating free intracellular glucose, they maintain the concentration gradient driving myocardial extraction of glucose from the bloodstream. Hexokinases are highly regulated proteins, subject to activation by insulin, hypoxia or ischaemia, and inhibition by their enzymatic product glucose-6-phosphate. In vitro and in many non-cardiac cell types, hexokinases have been shown to bind to the mitochondria, both increasing their phosphorylative capacity, and having a putative role in the anti-apoptotic function of protein kinase B (PKB)/Akt. Whether hexokinase-mitochondrial interaction is a dynamic and responsive process in the heart has been difficult to prove, but there is growing evidence that this association does indeed increase in response to insulin stimulation or ischaemia. In this review I discuss the relevance of hexokinase-mitochondrial interaction to cardiac glycolytic control, our interpretation of ¹⁸FDG cardiac PET scans, and its possible role in protecting the myocardium from ischaemic injury.     

A dual role for integrin‐linked kinase and β1‐integrin in modulating cardiac aging

Cardiac performance decreases with age, which is a major risk factor for cardiovascular disease and mortality in the aging human population, but the molecular mechanisms underlying cardiac aging are still poorly understood. Investigating the role of integrin‐linked kinase (ilk) and β1‐integrin (myospheroid, mys) in Drosophila, which colocalize near cardiomyocyte contacts and Z‐bands, we find that reduced ilk or mys function prevents the typical changes of cardiac aging seen in wildtype, such as arrhythmias. In particular, the characteristic increase in cardiac arrhythmias with age is prevented in ilk and mys heterozygous flies with nearly identical genetic background, and they live longer, in line with previous findings in Caenorhabditis elegans for ilk and in Drosophila for mys. Consistent with these findings, we observed elevated β1‐integrin protein levels in old compared with young wild‐type flies, and cardiac‐specific overexpression of mys in young flies causes aging‐like heart dysfunction. Moreover, moderate cardiac‐specific knockdown of integrin‐linked kinase (ILK)/integrin pathway‐associated genes also prevented the decline in cardiac performance with age. In contrast, strong cardiac knockdown of ilk or ILK‐associated genes can severely compromise cardiac integrity, including cardiomyocyte adhesion and overall heart function. These data suggest that ilk/mys function is necessary for establishing and maintaining normal heart structure and function, and appropriate fine‐tuning of this pathway can retard the age‐dependent decline in cardiac performance and extend lifespan. Thus, ILK/integrin‐associated signaling emerges as an important and conserved genetic mechanism in longevity, and as a new means to improve age‐dependent cardiac performance, in addition to its vital role in maintaining cardiac integrity.