Repetitive hypoglycemia reduces activation of glucose-responsive neurons in C1 and C3 medullary brain regions to subsequent hypoglycemia

Kakall, Zohra M.; Kavurma, Mary M.; Cohen, E. Myfanwy; Howe, Peter; Nedoboy, Polina E.; Pilowsky, Paul M.

doi:10.1152/ajpendo.00051.2019

Cited by 10 publications

(12 citation statements)

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“…While we did not directly measure brain tissue consumption of BHB, we can speculate on the basis of BHB measurements in the cerebral venous blood that central glucose-inhibited neurons (i.e., neurons that increase their firing rate in the presence of low glucose) were not sufficiently activated until a substantial amount of BHB disappeared from the circulation, which manifested as a delayed increase in ASNA and epinephrine release. One of the important brain nuclei necessary for the CRR and specifically for the sympathetically mediated epinephrine secretion is the C1 area in the rostral ventrolateral medulla [ 24 , 41 ]. In our study, a smaller proportion of activated C1 neurons in KD-fed rats may indicate a delayed response to hypoglycemia due to the time-course of Fos expression, which is reported to peak at 2 h post stimulus in the medulla [ 42 ]; however, in the absence of a longer time-course (e.g., 3 h post insulin), lower (but not delayed) activation of C1 neurons cannot be excluded.…”

Section: Discussionmentioning

confidence: 99%

“…Brainstem ( n = 3 per treatment group) was sectioned coronally at 40 µm in 1:5 series. Free-floating sections underwent routine immunohistochemistry [ 24 ]. Primary antibodies for adrenal gland immunohistochemistry were anti-PNMT (phenylethanolamine- N -methyltransferase, a marker for epinephrine-producing cells [ 30 ]; 1:1000, rabbit polyclonal, generated and characterized by P.R.…”

Section: Methodsmentioning

confidence: 99%

“…For that reason, and the fact that glucagon injections are less effective in patients who follow a low-carbohydrate diet [ 22 ], our study focused specifically on the role of the sympathoadrenal system and epinephrine, which are expected to be the major contributors to the CRR in the setting of type 1 diabetes. Therefore, the aim of this study was to test the effects of dietary ketosis, induced by a 3 week KD, on components of the sympathoadrenal CRR to severe insulin-induced hypoglycemia in healthy, nondiabetic rats, by measuring adrenal sympathetic nerve activity (ASNA), adrenal gland activity, and epinephrine release, as well as the activation state of catecholaminergic C1 neurons in the brainstem, which are glucose-sensitive and involved in the hypoglycemic CRR [ 23 , 24 ]. The adrenal sympathetic nerve, unlike renal, lumbar, or muscle sympathetic nerves, is activated by hypoglycemia independent of elevated insulin levels [ 25 ] and can be acutely recorded in anesthetized rats [ 26 ].…”

Section: Introductionmentioning

confidence: 99%

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Slow but Steady—The Responsiveness of Sympathoadrenal System to a Hypoglycemic Challenge in Ketogenic Diet-Fed Rats

2021

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The sympathoadrenal counterregulatory response to hypoglycemia is critical for individuals with type 1 diabetes due to impaired ability to produce glucagon. Ketogenic diets (KD) are an increasingly popular diabetes management tool; however, the effects of KD on the sympathoadrenal response are largely unknown. Here, we determined the effects of KD-induced ketosis on the sympathoadrenal response to a single insulin-induced hypoglycemic challenge. We investigated how a 3 week KD feeding regimen affected the main components of the sympathoadrenal counterregulatory response: adrenal sympathetic nerve activity (ASNA), adrenal gland activity, plasma epinephrine, and brainstem glucose-responsive C1 neuronal activation in anesthetized, nondiabetic male Sprague-Dawley rats. Rats on KD had similar blood glucose (BG) levels and elevated ketone body β-hydroxybutyrate (BHB) levels compared to the control Chow diet group. All KD rats responded to hypoglycemia with a robust increase in ASNA, which was initiated at significantly lower BG levels compared to Chow-fed rats. The delay in hypoglycemia-induced ASNA increase was concurrent with rapid disappearance of BHB from cerebral and peripheral circulation. Adrenal gland activity paralleled epinephrine and ASNA response. Overall, KD-induced ketosis was associated with initiation of the sympathoadrenal response at lower blood glucose levels; however, the magnitude of the response was not diminished.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Slow but Steady—The Responsiveness of Sympathoadrenal System to a Hypoglycemic Challenge in Ketogenic Diet-Fed Rats

2021

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“…It is well established that acute IHx in rodents under anesthesia produces long lasting sympathoexcitation ( Dick et al, 2007 ; Xing and Pilowsky, 2010 ; Roy et al, 2018 ; Farnham et al, 2019 ), which can be blocked at the level of carotid bodies, the spinal cord, and brainstem ( Kakall et al, 2018b ; Kim et al, 2018 ; Farnham et al, 2019 ). The involvement of the sympathetic system in glucose regulation is similarly well established and involves regions within the hypothalamus ( Frohman and Bernardis, 1971 ; Grayson et al, 2013 ) including the ventromedial hypothalamus ( Meek et al, 2016 ; Shimazu and Minokoshi, 2017 ) and paraventricular nucleus ( Sharpe et al, 2013 ; Menuet et al, 2014 ; Zhao et al, 2017 ), the brainstem ( Verberne and Sartor, 2010 ; Kakall et al, 2019 ), the adrenal gland ( Jun et al, 2014 ), and carotid bodies ( López-Barneo, 2003 ). Increases in blood glucose following acute, conscious IHx can be blocked by adrenergic blockade or adrenal medullectomy ( Rafacho et al, 2013 ; Jun et al, 2014 ) indicating sympathetic involvement via catecholamine release.…”

Section: Discussionmentioning

confidence: 99%

Pentobarbital Anesthesia Suppresses the Glucose Response to Acute Intermittent Hypoxia in Rat

2021

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A key feature of sleep disordered breathing syndromes, such as obstructive sleep apnea is intermittent hypoxia. Intermittent hypoxia is well accepted to drive the sympathoexcitation that is frequently associated with hypertension and diabetes, with measurable effects after just 1 h. The aim of this study was to directly measure the glucose response to 1 h of acute intermittent hypoxia in pentobarbital anesthetized rats, compared to conscious rats. However, we found that while a glucose response is measurable in conscious rats exposed to intermittent hypoxia, it is suppressed in anesthetized rats. Intermittent hypoxia for 1, 2, or 8 h increased blood glucose by 0.7 ± 0.1 mmol/L in conscious rats but had no effect in anesthetized rats (−0.1 ± 0.2 mmol/L). These results were independent of the frequency of the hypoxia challenges, fasting state, vagotomy, or paralytic agents. A supraphysiological challenge of 3 min of hypoxia was able to induce a glycemic response indicating that the reflex response is not abolished under pentobarbital anesthesia. We conclude that pentobarbital anesthesia is unsuitable for investigations into glycemic response pathways in response to intermittent hypoxia in rats.

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“…The rat is a particularly useful model to study the neuroendocrine regulation of the CRR to acute and recurrent hypoglycemia, particularly the Sprague-Dawley and Wistar rats, which have been the workhorse of the hypoglycemia field for the last 30 years. The hyperinsulinemic-hypoglycemic clamp, together with insulininduced hypoglycemia and 2-DG induced glucoprivation, have been extensively used in Sprague-Dawley rats to investigate CRR, glucoprivic feeding and impaired awareness of hypoglycemia (49)(50)(51)(52)(53)(54)(55)(56). This latter aspect of hypoglycemia "awareness" can be studied using a conditioned place preference test, which has so far been validated in rats but not in mice (57), largely because of the more rapid induction of defective counter-regulation in rats and their tractability for behavioral tests.…”

Section: Ratsmentioning

confidence: 99%

Brain-Body Control of Glucose Homeostasis—Insights From Model Organisms

Macdonald

Yang

et al. 2021

Front. Endocrinol.

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Tight regulation of blood glucose is essential for long term health. Blood glucose levels are defended by the correct function of, and communication between, internal organs including the gastrointestinal tract, pancreas, liver, and brain. Critically, the brain is sensitive to acute changes in blood glucose level and can modulate peripheral processes to defend against these deviations. In this mini-review we highlight select key findings showcasing the utility, strengths, and limitations of model organisms to study brain-body interactions that sense and control blood glucose levels. First, we discuss the large platform of genetic tools available to investigators studying mice and how this field may yet reveal new modes of communication between peripheral organs and the brain. Second, we discuss how rats, by virtue of their size, have unique advantages for the study of CNS control of glucose homeostasis and note that they may more closely model some aspects of human (patho)physiology. Third, we discuss the nascent field of studying the CNS control of blood glucose in the zebrafish which permits ease of genetic modification, large-scale measurements of neural activity and live imaging in addition to high-throughput screening. Finally, we briefly discuss glucose homeostasis in drosophila, which have a distinct physiology and glucoregulatory systems to vertebrates.

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Repetitive hypoglycemia reduces activation of glucose-responsive neurons in C1 and C3 medullary brain regions to subsequent hypoglycemia

Cited by 10 publications

References 65 publications

Slow but Steady—The Responsiveness of Sympathoadrenal System to a Hypoglycemic Challenge in Ketogenic Diet-Fed Rats

Slow but Steady—The Responsiveness of Sympathoadrenal System to a Hypoglycemic Challenge in Ketogenic Diet-Fed Rats

Pentobarbital Anesthesia Suppresses the Glucose Response to Acute Intermittent Hypoxia in Rat

Brain-Body Control of Glucose Homeostasis—Insights From Model Organisms

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