BOLD signal physiology: Models and applications.

The BOLD contrast mechanism has a complex relationship with functional brain activity, oxygen metabolism, and neurovascular factors. Accurate interpretation of the BOLD signal for neuroscience and clinical applications necessitates a clear understanding of the sources of BOLD contrast and its relationship to underlying physiology. This review describes the physiological components that contribute to the BOLD signal and the steady-state calibrated BOLD models that enable quantification of functional changes with a separate challenge paradigm. The principles derived from these biophysical models are then used to interpret BOLD measurements in different neurological disorders in the presence of confounding vascular factors related to disease.

[Switching and stopping antidepressants]. / Recommandations pour switcher et arrêter les antidépresseurs.

Major depressive disorder (MDD) is a common, typically recurrent, sometimes chronic and very disabling disorder, with a lifetime prevalence of 20%. Moreover, antidepressant treatments may be partially effective. Studies have found that up to 60% of patients with MDD do not fully respond to the first antidepressant prescribed. Thus, switching antidepressants is a common strategy for antidepressant non-responders. When switching between antidepressants, an appropriate switching strategy should be used, depending on the characteristics of the first and the second antidepressant and patient's background. Patients should be informed that antidepressants can cause discontinuation symptoms if stopped abruptly after prolonged used. Relapse and exacerbation of depression can also occur during a switch. Thus, all antidepressant switches must be carried out cautiously and under close observation. This article summarizes the recommendations for an optimal antidepressant switch.

Investigation of the confounding effects of vasculature and metabolism on computational anatomy studies.

Computational anatomy studies typically use T1-weighted magnetic resonance imaging contrast to look at local differences in cortical thickness or grey matter volume across time or subjects. This type of analysis is a powerful and non-invasive tool to probe anatomical changes associated with neurodevelopment, aging, disease or experience-induced plasticity. However, these comparisons could suffer from biases arising from vascular and metabolic subject- or time-dependent differences. Differences in blood flow and volume could be caused by vasodilation or differences in vascular density, and result in a larger signal contribution of the blood compartment within grey matter voxels. Metabolic changes could lead to differences in dissolved oxygen in brain tissue, leading to T1 shortening. Here, we analyze T1 maps and T1-weighted images acquired during different breathing conditions (ambient air, hypercapnia (increased CO2) and hyperoxia (increased O2)) to evaluate the effect size that can be expected from changes in blood flow, volume and dissolved O2 concentration in computational anatomy studies. Results show that increased blood volume from vasodilation during hypercapnia is associated with an overestimation of cortical thickness (1.85%) and grey matter volume (3.32%), and that both changes in O2 concentration and blood volume lead to changes in the T1 value of tissue. These results should be taken into consideration when interpreting existing morphometry studies and in future study design. Furthermore, this study highlights the overlap in structural and physiological MRI, which are conventionally interpreted as two independent modalities.

Pigmented skin patches without scleroderma as a predominant clinical symptom revealing systemic sclerosis.

Skin induration remains the major clinical symptom of systemic sclerosis (SSc), an autoimmune disease with potentially life-threatening visceral involvement. However, skin induration can be absent in some patients, making the diagnosis difficult to confirm and leading to delay in management. Skin pigmentation abnormalities have been reported in patients with SSc, and can be important to recognize for diagnosis. We report two patients who developed hyperpigmented skin patches without any sign of scleroderma, as a major clinical skin symptom of incipient SSc.

[Therapeutic effects of oxytocin in autism: Current status of the research]. / Applications thérapeutiques de l'ocytocine dans l'autisme : premiers résultats et pistes de recherche.

The neuropeptide oxytocin (OT) is an evolutionary highly conserved molecule that plays a part in the regulation of complex social cognition and behaviours. From a pathophysiological point of view, several studies have evidenced dysfunctions of the oxytocinergic system in autism spectrum disorders (ASD): a lowering of plasma OT and genetic or epigenetic anomalies of the OT receptor. Therefore, some authors have hypothesized that an abnormality in the OT neurotransmission may account for several features of autism and that a treatment restoring a normal OT pathway functioning could improve social abilities. OT administration has thus been used in clinical trials, especially in groups of subjects suffering from autism. Some studies found that OT decreased repetitive behaviours, enhanced emotional understanding of speech intonation, improved performance of the Reading the Mind in the Eyes Test and reinforced cooperation. Nevertheless, the findings of the OT administration studies on clinical samples show great diversity. The context, the personality and childhood experiences of the subject could be moderators influencing the effect of exogenous OT. Besides, three mechanisms could play a part in the action of OT on ASD social symptoms: anxiety reduction (with a lowering in the hypothalamic-pituitary-adrenal axis responsiveness and in the amygdale reactivity to social stimuli), increased affiliative motivation (involving the dopaminergic pathway and several regions of the social brain) and enhanced perceptual selectivity and social stimuli salience. To conclude, OT could be a promising molecule used as a treatment to promote social behaviours, helping individuals with ASD to develop new relationships. OT could be administered during a cognitive-behavioural therapy to reinforce the efficacy of such procedures. More studies are needed, on larger samples, to investigate the safety and efficacy of OT administration and to specify optimal dosages and characteristics of patients who may benefit from this treatment.

Circulating CXCR5+CD4+helper T cells in systemic lupus erythematosus patients share phenotypic properties with germinal center follicular helper T cells and promote antibody production.

OBJECTIVE: Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by the production of autoantibodies. Recently, a specific highly activated T helper cell subset, follicular helper T (Tfh) cell, has emerged as a key immunoregulator of germinal center (GC) formation and high-affinity antibody production. To identify the pathophysiological role of Tfh cells in SLE patients, we compared the phenotypic and functional properties of circulating Tfh-like cells in lupus patients to GC-Tfh cells, and correlated the percentage of Tfh-like cells with autoantibody production and SLE disease activity. METHODS: Peripheral blood was collected from 29 lupus patients and 25 healthy controls. Tonsils were obtained surgically from non-SLE controls and used as a source of GC-Tfh cells. Tfh cells were defined by their signature surface markers (CXCR5, ICOS, CD57, PD-1 and BTLA) via flow cytometry. IL-21 expression levels from Tfh cells were measured by real-time PCR and intracellular staining. The function of Tfh cells was carried out by co-culture of Tfh cells and autologous B cells in vitro. IgG in the culture supernatant was detected by ELISA. RESULTS: The frequency of circulating Tfh-like cells was significantly increased in SLE patients compared to healthy controls (p < 0.05). The Tfh-like cells not only display similar phenotypes and signature cytokines with GC-Tfh cells, but also are capable of driving B cells to differentiate into IgG-secreting plasma cells in vitro. In addition, the frequency of Tfh-like cells correlated positively with the percentage of circulating plasmablasts, levels of serum anti-dsDNA antibodies and ANA. CONCLUSION: The accumulated circulating Tfh-like cells in lupus patients share phenotypic and functional properties with GC-Tfh cells. Tfh-like cells may serve as perpetuators in the pathogenesis of SLE by enhancing the self-reactive B cell clones to further differentiate into auto antibody-producing plasmablasts, and ultimately cause autoimmunity.

Surgical management of Moyamoya disease and syndrome: Current concepts and personal experience.

In this focus, we review, in the light of the recent literature, the modalities and indications of surgical cerebral revascularization for Moyamoya (MM) disease or syndrome. We also report our experience in the surgical management of adult MM. In symptomatic forms, with presence of severe disturbances of perfusion or cerebrovascular reactivity on multimodal imaging work-up, the risks of recurrent ischemic or hemorrhagic stroke is high (respectively 10-13%/yr and 2-7%/yr). The objective of treatment is to augment cerebral perfusion (in ischemic forms) or to reduce lenticulo-striate neovessel overload (in hemorrhagic forms), by initiating the development of a cortical neovascularization and/or by directly increasing cerebral blood flow. The risk of immediate postoperative death or stroke is similar between indirect and direct or combined techniques and respectively 0-0.5% and 3-6%, provided a strict perioperative anesthetic management is applied (normocapnia, normoxia and controlled hypertension). Indirect techniques (i.e. encephalo-duro-arterio-myo-periosteo-synangiosis or multiple burr-holes) are technically easy, allow wide cortical revascularization and are very efficient in children: absence of clinical recurrence in more than 95% of cases and presence of a good neovascularization in 83%. However, their effect is delayed for several months, the impact on the hemorrhagic risk is moderate and the global response is uncertain in adults. Direct (superficial temporal artery to middle cerebral artery bypass) or combined techniques improve cerebral blood flow immediately and significantly. They are associated with a higher rate of stroke-free survival at 5 years (95% vs 85%). A recent randomized study has proven that they could reduce the hemorrhagic risk by 2- to 3-fold in comparison with conservative treatment alone. However, their feasibility in children is limited by the very small size of vessels. We present also our results in the surgical management of 12 adult MM patients (mean age 41.3, sex ratio=1) operated between 2009 and 2014 (14 revascularization procedures: EDAMS 2, multiple burr-holes 1, combined revascularization procedures 11). MM types according to clinical presentation were the following: ischemic 8, hemorrhagic 2, combined 2. All patients were recently symptomatic, with recurrent ischemic/hemorrhagic events (2/3) or crescendo neurological deficit (1/3) in association with severe alterations of cerebral blood flow. Mean clinical and radiological follow-up was 22 months. Postoperative mRS at 6 months was improved or stable in 92%. None of the patients suffered recurring stroke. In conclusion, surgical treatment should be discussed quickly in symptomatic forms of MM (progressive or recurring) because of their poor outcome. Indirect techniques are favored in pediatric patients due to their simplicity and good clinical results. Direct, or preferentially combined techniques would be more effective in adult patients to prevent the recurrence of ischemic or hemorrhagic stroke.

Analysis of local properties during a scratch test on a polymeric surface using molecular dynamics simulations.

This work demonstrates a possible route to connect a particle (chain) based understanding with continuum mechanical questions about contact mechanics. The bond orientation, chain conformation and stress field of a polymer film were analyzed during scratch tests (tangential contact) using a molecular dynamics (MD) simulation approach. Scratch tests with a conical tip at constant scratching velocity were simulated on linear amorphous polymer surfaces at various temperatures and roughnesses of the tip and for various interactions between the tip and the particles of the polymer chains. The second Legendre polynomial (computed for small domains around the tip) gave the bond orientation inside the polymer film during sliding of the tip. The gyration tensor (layer-resolved in the direction of the polymer film thickness) provided information about the conformation of the polymer chains. These results allowed us to argue in favor of Briscoe's hypothesis (thin film sheared vs. "bulk" compressive behavior) concerning the friction properties of the polymer surfaces. Finally, the first stress measurements of the virial stress tensor (in sub-boxes placed in the MD cell) revealed a complex combination between compressive hydrostatic pressure and shear stress, which may be interpreted as a complex sheared domain at the interface.

The effect of surgically assisted rapid maxillary expansion on sleep architecture: an exploratory risk study in healthy young adults.

Maxillary transverse deficiencies (MTD) cause malocclusions. Rapid maxillary expansion treatment is commonly used treatment for correcting such deficiencies and has been found to be effective in improving respiration and sleep architecture in children with obstructive sleep apnoea (OSA). However, thus far, the effect of surgically assisted rapid maxillary expansion (SARME) treatment on sleep architecture and breathing of normal subjects has not been assessed. We hypothesised that sleep quality will improve after maxillary expansion treatment. The objective of this study is to access the effect of maxillary expansion treatment on sleep structure and respiratory functions in healthy young adults with severe MTD. This is a prospective and exploratory clinical study. Twenty-eight consecutive young adult patients (15 males and 13 females, mean age 20·6 ± 5·8 years) presenting with severe MTD at the orthodontic examination were recruited into the study. All the participants underwent a standardised SARME procedure (mean expansion 6·5 ± 1·8 and 8·2 ± 1·8 mm, intercanine and intermolar distance, respectively) to correct malocclusion caused by MTD. An overnight in-laboratory polysomnography, before and after the treatment, was performed. The mean follow-up time was 9 months. The main outcome parameters were the changes in sleep architecture, including sleep stages, arousals, slow-wave activity (SWA) and respiratory variables. Before surgery, young adult patients with MTD presented no evidence of sleep breathing problems. At baseline sleep recording, 7 of 28 (25%) had apnoea-hypopnoea index (AHI) ≥ 5 events per hour. No negative effect of the SARME was observed in questionnaires or sleep laboratory parameters. In the patients with a higher baseline AHI (AHI ≥ 5 h of sleep), we observed a reduction in AHI after surgical treatment (P = 0·028). SARME did not have a negative effect on any sleep or respiration parameters in healthy young individuals with MTD. It normalised the breathing index in the patients with a mild AHI index.

Magnetic resonance imaging of resting OEF and CMRO2 using a generalized calibration model for hypercapnia and hyperoxia.

We present a method allowing determination of resting cerebral oxygen metabolism (CMRO2) from MRI and end-tidal O2 measurements acquired during a pair of respiratory manipulations producing different combinations of hypercapnia and hyperoxia. The approach is based on a recently introduced generalization of calibrated MRI signal models that is valid for arbitrary combinations of blood flow and oxygenation change. Application of this model to MRI and respiratory data during a predominantly hyperoxic gas manipulation yields a specific functional relationship between the resting BOLD signal M and the resting oxygen extraction fraction OEF0. Repeating the procedure using a second, primarily hypercapnic, manipulation provides a different functional form of M vs. OEF0. These two equations can be readily solved for the two unknowns M and OEF0. The procedure also yields the resting arterial O2 content, which when multiplied by resting cerebral blood flow provides the total oxygen delivery in absolute physical units. The resultant map of oxygen delivery can be multiplied by the map of OEF0 to obtain a map of the resting cerebral metabolic rate of oxygen consumption (CMRO2) in absolute physical units. Application of this procedure in a group of seven human subjects provided average values of 0.35 ± 0.04 and 6.0 ± 0.7% for OEF0 and M, respectively in gray-matter (M valid for 30 ms echo-time at 3T). Multiplying OEF0 estimates by the individual values of resting gray-matter CBF (mean 52 ± 5 ml/100 g/min) and the measured arterial O2 content gave a group average resting CMRO2 value of 145 ± 30 µmol/100 g/min. The method also allowed the generation of maps depicting resting OEF, BOLD signal, and CMRO2.

Absolute quantification of resting oxygen metabolism and metabolic reactivity during functional activation using QUO2 MRI.

We have recently described an extension of calibrated MRI, which we term QUO2 (for QUantitative O(2) imaging), providing absolute quantification of resting oxidative metabolism (CMRO(2)) and oxygen extraction fraction (OEF(0)). By combining BOLD, arterial spin labeling (ASL) and end-tidal O(2) measurements in response to hypercapnia, hyperoxia and combined hyperoxia/hypercapnia manipulations, and the same MRI measurements during a task, a comprehensive set of vascular and metabolic measurements can be obtained using a generalized calibration model (GCM). These include the baseline absolute CBF in units of ml/100g/min, cerebrovascular reactivity (CVR) in units of %Δ CBF/mm Hg, M in units of percent, OEF(0) and CMRO(2) at rest in units of µmol/100g/min, percent evoked CMRO(2) during the task and n, the value for flow-metabolic coupling associated with the task. The M parameter is a calibration constant corresponding to the maximal BOLD signal that would occur upon removal of all deoxyhemoglobin. We have previously shown that the GCM provides estimates of the above resting parameters in grey matter that are in excellent agreement with literature. Here we demonstrate the method using functionally-defined regions-of-interest in the context of an activation study. We applied the method under high and low signal-to-noise conditions, corresponding respectively to a robust visual stimulus and a modified Stroop task. The estimates fall within the physiological range of literature values, showing the general validity of the GCM approach to yield non-invasively an extensive array of relevant vascular and metabolic parameters.

Task-related BOLD responses and resting-state functional connectivity during physiological clamping of end-tidal CO(2).

Carbon dioxide (CO(2)), a potent vasodilator, is known to have a significant impact on the blood-oxygen level dependent (BOLD) signal. With the growing interest in studying synchronized BOLD fluctuations during the resting state, the extent to which the apparent synchrony is due to variations in the end-tidal pressure of CO(2) (PETCO(2)) is an important consideration. CO(2)-related fluctuations in BOLD signal may also represent a potential confound when studying task-related responses, especially if breathing depth and rate are affected by the task. While previous studies of the above issues have explored retrospective correction of BOLD fluctuations related to arterial PCO(2), here we demonstrate an alternative approach based on physiological clamping of the arterial CO(2) level to a near-constant value. We present data comparing resting-state functional connectivity within the default-mode-network (DMN), as well as task-related BOLD responses, acquired in two conditions in each subject: 1) while subject's PETCO(2) was allowed to vary spontaneously; and 2) while controlling subject's PETCO(2) within a narrow range. Strong task-related responses and areas of maximal signal correlation in the DMN were not significantly altered by suppressing fluctuations in PETCO(2). Controlling PETCO(2) did, however, improve the performance of retrospective physiological noise correction techniques, allowing detection of additional regions of task-related response and resting-state connectivity in highly vascularized regions such as occipital cortex. While these results serve to further rule out systemic physiological fluctuations as a significant source of apparent resting-state network connectivity, they also demonstrate that fluctuations in arterial CO(2) are one of the factors limiting sensitivity in task-based and resting-state fMRI, particularly in regions of high vascular density. This must be considered when comparing subject groups who might exhibit differences in respiratory physiology or breathing patterns.

Elimination of visually evoked BOLD responses during carbogen inhalation: implications for calibrated MRI.

Breathing a mixture of 10% CO(2) with 90% O(2) (referred to here as carbogen-10) increases blood flow due to the vasodilatory effect of CO(2), and raises blood O(2) saturation due to the enriched oxygen level. These effects both tend to reduce the level of deoxygenated hemoglobin in brain tissues, thereby reducing the potential for further increases in BOLD contrast. In the present study, blocks of intense visual stimulation (60s) were presented amid longer blocks (180s) during which subjects breathed various fractional concentrations (0-100%) of carbogen-10 diluted with medical air. When breathing undiluted carbogen-10, the BOLD response to visual stimulation was reduced below the level of noise against the background of the carbogen-10 response. At these concentrations, the total (visual+carbogen) BOLD response amplitude (7.5±1.0%, n=6) converged toward that seen with carbogen alone (7.5±1.0%, n=6). In spite of the almost complete elimination of the visual BOLD response, pseudo-continuous arterial spin-labeling on a separate cohort indicated a largely preserved perfusion response (89±34%, n=5) to the visual stimulus during inhalation of carbogen-10. The previously discussed observations suggest that venous saturation can be driven to very high levels during carbogen inhalation, a finding which has significant implications for calibrated MRI techniques. The latter methods involve estimation of the relative change in venous O(2) saturation by expressing activation-induced BOLD signal increases as a fraction of the maximal BOLD signal M that would be observed as venous saturation approaches 100%. While the value of M has generally been extrapolated from much smaller BOLD responses induced using hypercapnia or hyperoxia, our results suggest that these effects could be combined through carbogen inhalation to obtain estimates of M based on larger BOLD increases. Using a hybrid BOLD calibration model taking into account changes in both blood flow and arterial oxygenation, we estimated that inhalation of carbogen-10 led to an average venous saturation of 91%, allowing us to compute an estimated M value of 9.5%.

[In a medical setting, why and how can the doctor identify the patient as a victim of abuse]. / Pourquoi et comment détecter les victimes d'abus dans la consultation médicale.

People who were victims of childhood abuse (sexual, emotional or physical), later on will develop psychosomatic illnesses and psychological problems. These health problems, sad consequences of past abuse, will bring them to consult a physician at one point or another. But, because these patients often do not talk about the ancient trauma, the physician is unaware of this past abuse and only treats the illness' symptoms. Abused people will also develop behavioral problems which put them repeatedly back into the position of victim, without realizing why. If this dysfunctional behavior is not identified as the result of trauma, these multi-abused patients will go from bad to worse, repeating in an endless cycle their role as victim. If the physician is able to identify this typical replay of victimization, the patient can be helped to become aware of and to avoid compulsive self-abusive behaviors which are discussed in the following article.

BOLD signal responses to controlled hypercapnia in human spinal cord.

Functional MRI of the spinal cord is challenging due to the small cross section of the cord and high level of physiological noise. Though blood oxygenation level-dependent (BOLD) contrast has been used to study specific responses of the spinal cord to various stimuli, it has not been demonstrated using a controlled stimulus. In this paper, we use hypercapnic manipulation to study the sensitivity and specificity of functional MRI in the human cervical spinal cord. Simultaneous MR imaging in the brain and spinal cord was performed for direct comparison with the brain, in which responses to hypercapnia have been more extensively characterized. Original contributions include: (i) prospectively controlled hypercapnic changes in end-tidal PCO(2), (ii) simultaneous recording of BOLD responses in the brain and spinal cord, and (iii) generation of statistical maps of BOLD responses throughout the brain and spinal cord, taking into account physiological noise sources. Results showed significant responses in all subjects both in the brain and the spinal cord. In anatomically-defined regions of interest, mean percent changes were 0.6% in the spinal cord and 1% in the brain. Analysis of residual variance demonstrated significantly larger contribution of physiological noise in the spinal cord (P<0.005). To obtain more reliable results from fMRI in the spinal cord, it will be necessary to improve sensitivity through the use of highly parallelized coil arrays and better modeling of physiological noise. Finely, we believe that the use of controlled global stimuli, such as hypercapnia, will help assess the effectiveness of new acquisition techniques.

[Sexual abuse: a cause for psychosomatic illnesses]. / Les abus sexuels: une cause des maladies psychosomatiques.

A human being is a psychosomatic entity, an inseparable mind/body unit. Psychosomatic illness is caused by a break of this vulnerable internal equilibrium from important emotional perturbations provoked by experiences of abuse. Patients rarely consult their physician for abuse they suffered, and they often keep it a lifetime secret. Moreover, since there is a latency period between the abuse and the emergence of physical symptoms, neither the physician nor the patient realize how past abuse and present symptoms are related. Symptomatic treatment cannot treat the root pathologies and thus, psychosomatic illnesses most commonly become chronic.

Serotonergic paraneurones in the female mouse urethral epithelium and their potential role in peripheral sensory information processing.

AIM: The mechanisms underlying detection and transmission of sensory signals arising from visceral organs, such as the urethra, are poorly understood. Recently, specialized ACh-expressing cells embedded in the urethral epithelium have been proposed as chemosensory sentinels for detection of bacterial infection. Here, we examined the morphology and potential role in sensory signalling of a different class of specialized cells that express serotonin (5-HT), termed paraneurones. METHODS: Urethrae, dorsal root ganglia neurones and spinal cords were isolated from adult female mice and used for immunohistochemistry and calcium imaging. Visceromotor reflexes (VMRs) were recorded in vivo. RESULTS: We identified two morphologically distinct groups of 5-HT+ cells with distinct regional locations: bipolar-like cells predominant in the mid-urethra and multipolar-like cells predominant in the proximal and distal urethra. Sensory nerve fibres positive for calcitonin gene-related peptide, substance P, and TRPV1 were found in close proximity to 5-HT+ paraneurones. In vitro 5-HT (1 µm) stimulation of urethral primary afferent neurones, mimicking 5-HT release from paraneurones, elicited changes in the intracellular calcium concentration ([Ca2+ ]i ) mediated by 5-HT2 and 5-HT3 receptors. Approximately 50% of 5-HT responding cells also responded to capsaicin with changes in the [Ca2+ ]i . In vivo intra-urethral 5-HT application increased VMRs induced by urethral distention and activated pERK in lumbosacral spinal cord neurones. CONCLUSION: These morphological and functional findings provide insights into a putative paraneurone-neural network within the urethra that utilizes 5-HT signalling, presumably from paraneurones, to modulate primary sensory pathways carrying nociceptive and non-nociceptive (mechano-sensitive) information to the central nervous system.

Antisense oligodeoxynucleotide to the cystic fibrosis transmembrane conductance regulator inhibits cyclic AMP-activated but not calcium-activated cell volume reduction in a human pancreatic duct cell line.

Cystic fibrosis (CF) is characterized by a defect in cAMP-regulated chloride channels in epithelial cells. The CF gene product CF transmembrane conductance regulator (CFTR) is expressed in the apical membrane of pancreatic duct cells, and mutant CFTR accounts for the pathology in the CF pancreas. PANC 1, a pancreatic duct cell line, has not been considered a good model for studying CFTR and pancreatic chloride transport because CFTR mRNA and protein are undetectable using standard methods. Using electronic cell sizing and cell volume reduction under isotonic conditions, PANC 1 cells were found to possess both cAMP and calcium-activated chloride conductances. Using CFTR antisense oligodeoxynucleotides, the cAMP-activated conductance could be specifically inhibited in a concentration- and time-dependent manner. These findings demonstrate that PANC 1 cells express CFTR and a CFTR-independent calcium-activated chloride channel. With electronic cell sizing and CFTR antisense oligodeoxynucleotides, PANC 1 cells can provide an ideal system for the study of pancreatic duct cell physiology and pathophysiology with respect to the role of CFTR in the pancreas. These findings also suggest that antisense oligodeoxynucleotides may provide a more sensitive yet highly specific means of detecting low levels of expression of CFTR than currently available.

Effects of Npt2 gene ablation and low-phosphate diet on renal Na(+)/phosphate cotransport and cotransporter gene expression.

The renal Na(+)/phosphate (Pi) cotransporter Npt2 is expressed in the brush border membrane (BBM) of proximal tubular cells. We examined the effect of Npt2 gene knockout on age-dependent BBM Na(+)/Pi cotransport, expression of Na(+)/Pi cotransporter genes Npt1, Glvr-1, and Ram-1, and the adaptive response to chronic Pi deprivation. Na(+)/Pi cotransport declines with age in wild-type mice (Npt2(+/+)), but not in mice homozygous for the disrupted Npt2 allele (Npt2(-/-)). At all ages, Na(+)/Pi cotransport in Npt2(-/-) mice is approximately 15% of that in Npt2(+/+) littermates. Only Npt1 mRNA abundance increases with age in Npt2(+/+) mice, whereas Npt1, Glvr-1, and Ram-1 mRNAs show an age-dependent increase in Npt2(-/-) mice. Pi deprivation significantly increases Na(+)/Pi cotransport, Npt2 protein, and mRNA in Npt2(+/+) mice. In contrast, Pi-deprived Npt2(-/-) mice fail to show the adaptive increase in transport despite exhibiting a fall in serum Pi. We conclude that (a) Npt2 is a major determinant of BBM Na(+)/Pi cotransport; (b) the age-dependent increase in Npt1, Glvr-1, and Ram-1 mRNAs in Npt2(-/-) mice is insufficient to compensate for loss of Npt2; and (c) Npt2 is essential for the adaptive BBM Na(+)/Pi cotransport response to Pi deprivation.