Your search keyword '"Denholm, Barry"' showing total 3 results

1. NHA1 is a cation/proton antiporter essential for the water-conserving functions of the rectal complex in Tribolium castaneum.

Author

Naseem, Muhammad T., Beaven, Robin, Koyama, Takashi, Naz, Sehrish, Sheng-yuan Su, Leader, David P., Klaerke, Dan A., Calloe, Kirstine, Denholm, Barry, and Halberg, Kenneth V.

Subjects

RED flour beetle, PHYSIOLOGY, GENE silencing, BIOLOGICAL fitness, TRIBOLIUM, CRYPTOCURRENCIES

Abstract

More than half of all extant metazoan species on earth are insects. The evolutionary success of insects is linked with their ability to osmoregulate, suggesting that they have evolved unique physiological mechanisms to maintain water balance. In beetles (Coleoptera)—the largest group of insects—a specialized rectal (“cryptonephridial”) complex has evolved that recovers water from the rectum destined for excretion and recycles it back to the body. However, the molecular mechanisms underpinning the remarkable water-conserving functions of this system are unknown. Here, we introduce a transcriptomic resource, BeetleAtlas.org, for the exceptionally desiccation- tolerant red flour beetle Tribolium castaneum, and demonstrate its utility by identifying a cation/H+ antiporter (NHA1) that is enriched and functionally significant in the Tribolium rectal complex. NHA1 localizes exclusively to a specialized cell type, the leptophragmata, in the distal region of the Malpighian tubules associated with the rectal complex. Computational modeling and electrophysiological characterization in Xenopus oocytes show that NHA1 acts as an electroneutral K+/H+ antiporter. Furthermore, genetic silencing of Nha1 dramatically increases excretory water loss and reduces organismal survival during desiccation stress, implying that NHA1 activity is essential for maintaining systemic water balance. Finally, we show that Tiptop, a conserved transcription factor, regulates NHA1 expression in leptophragmata and controls leptophragmata maturation, illuminating the developmental mechanism that establishes the functions of this cell. Together, our work provides insights into the molecular architecture underpinning the function of one of the most powerful water-conserving mechanisms in nature, the beetle rectal complex. [ABSTRACT FROM AUTHOR]

Published

2023

2. A unique Malpighian tubule architecture in Tribolium castaneum informs the evolutionary origins of systemic osmoregulation in beetles.

Author

Takashi Koyama, Naseem, Muhammad Tayyib, Kolosov, Dennis, Vo, Camilla Trang, Mahon, Duncan, Seger Jakobsen, Amanda Sofie, Jensen, Rasmus Lycke, Denholm, Barry, O'Donnell, Michael, and Halberg, Kenneth Veland

Subjects

RED flour beetle, BEETLES, OSMOREGULATION, SALINE waters

Abstract

Maintaining internal salt and water balance in response to fluctuating external conditions is essential for animal survival. This is particularly true for insects as their high surface-to-volume ratio makes them highly susceptible to osmotic stress. However, the cellular and hormonal mechanisms that mediate the systemic control of osmotic homeostasis in beetles (Coleoptera), the largest group of insects, remain largely unidentified. Here, we demonstrate that eight neurons in the brain of the red flour beetle Tribolium castaneum respond to internal changes in osmolality by releasing diuretic hormone (DH) 37 and DH47--homologs of vertebrate corticotropin-releasing factor (CRF) hormones--to control systemic water balance. Knockdown of the gene encoding the two hormones (Urinate, Urn8) reduces Malpighian tubule secretion and restricts organismal fluid loss, whereas injection of DH37 or DH47 reverses these phenotypes. We further identify a CRF-like receptor, Urinate receptor (Urn8R), which is exclusively expressed in a functionally unique secondary cell in the beetle tubules, as underlying this response. Activation of Urn8R increases K+ secretion, creating a lumen-positive transepithelial potential that drives fluid secretion. Together, these data show that beetle Malpighian tubules operate by a fundamentally different mechanism than those of other insects. Finally, we adopt a fluorescent labeling strategy to identify the evolutionary origin of this unusual tubule architecture, revealing that it evolved in the last common ancestor of the higher beetle families. Our work thus uncovers an important homeostatic program that is key to maintaining osmotic control in beetles, which evolved parallel to the radiation of the "advanced" beetle lineages. [ABSTRACT FROM AUTHOR]

Published

2021

3. A unique Malpighian tubule architecture in Tribolium castaneum informs the evolutionary origins of systemic osmoregulation in beetles.

Author

Koyama T, Naseem MT, Kolosov D, Vo CT, Mahon D, Jakobsen ASS, Jensen RL, Denholm B, O'Donnell M, and Halberg KV

Subjects

Animals, Brain cytology, Brain physiology, Insect Hormones metabolism, Malpighian Tubules cytology, Neurons physiology, Tribolium genetics, Evolution, Molecular, Malpighian Tubules physiology, Tribolium physiology, Water-Electrolyte Balance

Abstract

Maintaining internal salt and water balance in response to fluctuating external conditions is essential for animal survival. This is particularly true for insects as their high surface-to-volume ratio makes them highly susceptible to osmotic stress. However, the cellular and hormonal mechanisms that mediate the systemic control of osmotic homeostasis in beetles (Coleoptera), the largest group of insects, remain largely unidentified. Here, we demonstrate that eight neurons in the brain of the red flour beetle Tribolium castaneum respond to internal changes in osmolality by releasing diuretic hormone (DH) 37 and DH47-homologs of vertebrate corticotropin-releasing factor (CRF) hormones-to control systemic water balance. Knockdown of the gene encoding the two hormones ( Urinate , Urn8 ) reduces Malpighian tubule secretion and restricts organismal fluid loss, whereas injection of DH37 or DH47 reverses these phenotypes. We further identify a CRF-like receptor, Urinate receptor (Urn8R), which is exclusively expressed in a functionally unique secondary cell in the beetle tubules, as underlying this response. Activation of Urn8R increases K + secretion, creating a lumen-positive transepithelial potential that drives fluid secretion. Together, these data show that beetle Malpighian tubules operate by a fundamentally different mechanism than those of other insects. Finally, we adopt a fluorescent labeling strategy to identify the evolutionary origin of this unusual tubule architecture, revealing that it evolved in the last common ancestor of the higher beetle families. Our work thus uncovers an important homeostatic program that is key to maintaining osmotic control in beetles, which evolved parallel to the radiation of the "advanced" beetle lineages., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021