Introduction

The cerebral microvascular endothelium is distinguished by the presence of the blood–brain barrier (BBB), consisting of: (1) epithelial-like tight junctions that restrict paracellular permeability; (2) highly regulated membrane transporters that mediate the passage of molecules through the endothelium; and (3) metabolic enzymes. In concert with astrocytes, pericytes, neurons and the extracellular matrix, the BBB forms a neurovascular unit that protects the brain from circulating neurotoxic substances while maintaining nutrients and ions in the brain at levels necessary for neuronal function. Failure of the BBB is a critical event in the progression of several neurological diseases, indicating that the BBB may present a novel therapeutic target in these diseases if the mechanisms of BBB breakdown can be elucidated [1].

Microvascular complications of diabetes mellitus include diminished perfusion, abnormal endothelial proliferation, and increased permeability [2, 3]. Although diabetes is associated with increased risk of neurodegeneration [4] and dementia [5], the specific effects of diabetes on the BBB remain controversial. Diabetes has been associated with increased BBB permeability in some studies [69], whereas others have indicated that the BBB is maintained in diabetes [1012].

Occludin (also known as OCLN), one of the extracellular components of the tight junction, restricts permeability to low molecular mass molecules and increases electrical resistance of barrier tissues; loss of occludin expression and/or translocation of occludin from the junction is associated with increased BBB permeability in diseases including inflammation, ischaemia and HIV encephalitis [1]. Occludin is also decreased following streptozotocin treatment in rats both in cerebral [13] and in retinal microvasculature [14]. Decreased occludin content in diabetic retinopathy may result from degradation by matrix metalloproteinases (MMPs) [15]. Expression and activity of the gelatinases MMP-2 and MMP-9 are increased by hyperglycaemia in vitro [3] and elevated in patients with type 1 [16] and type 2 [17] diabetes. Furthermore, MMP-2 and MMP-9 are known mediators of BBB opening [18, 19] and occludin proteolysis [20]. It is therefore possible that diabetes leads to compromise of BBB tight junction via stimulation of MMP activity. To address this hypothesis, we examined the effects of streptozotocin treatment on BBB permeability in the rat using in situ brain perfusion, and its effects on the expression of the BBB tight junction proteins occludin, claudin-5 and zona occludens 1 (ZO-1, also known as tight junction protein 1 or TJP1) using real-time PCR, immunoblot and immunofluorescence techniques. MMP activity in plasma was investigated by a fluorimetric gelatinase assay and by gel zymography.

Materials and methods

Animals and reagents

All animal protocols in this study were approved by the University of Arizona Institutional Animal Care and Use Committee and conform to National Institutes of Health guidelines stated in ‘Principles of laboratory animal care’ (NIH publication no. 85-23, revised 1985). Male Sprague–Dawley rats (3–4 months old, 270–330 g) were purchased from Harlan (Indianapolis, IN, USA). Rats were fasted for 6 h prior to i.p. injection of either 60 mg/kg streptozotocin in sterile 0.9% saline or saline alone. Following injection, animals were returned to their cages, maintained under standard 12 h light–dark cycle, and given free access to food and water for the remainder of the study. Animals included in the insulin intervention studies were given insulin dissolved in sterile saline, 8 U/kg via intraperitoneal injection twice daily starting on day 7, or a single dose 2 h prior to in situ brain perfusion in the acute insulin study. Hyperglycaemia was confirmed by urine test strips prior to commencement of insulin treatment, and animals were monitored following insulin injection for signs of severe hypoglycaemia (altered behaviour, ataxia, convulsions). Animals in the acute hyperglycaemia study were anaesthetised prior to injection of a 500-μl bolus of either 50% glucose in saline or saline alone, followed by blood sampling and in situ brain perfusion within 10 min. For all endpoints, animals were anaesthetised via intramuscular injection of 1 ml/kg of a cocktail containing ketamine (78.3 mg/ml), acepromazine (0.6 mg/ml) and xylazine (3.1 mg/ml) prior to in situ brain perfusion or decapitation. Terminal blood samples were collected from the tail veins of all animals prior to their being killed. Samples were tested for blood glucose, ketones and lipids with an analyser (CardioChek P·A; Polymer Technology Systems, Indianapolis, IN, USA) and/or centrifuged for plasma and stored at −20°C. Animals were considered diabetic if blood glucose was >16.7 mmol/l; streptozotocin-treated animals with blood glucose <16.7 mmol/l were excluded from the study.

Rabbit polyclonal anti-ZO-1 and anti-occludin, and mouse monoclonal anti-claudin-5 (also known as CLDN5) were purchased from Zymed (San Francisco, CA, USA). Horseradish peroxidase (HRP)-conjugated secondary antibodies were purchased from Amersham (Springfield, IL, USA). Alexafluor 488-conjugated secondary antibodies were obtained from Molecular Probes (Eugene, OR, USA). [14C]Sucrose (specific activity 37 MBq) was purchased from Amersham. All other reagents were purchased from Sigma (St. Louis, MO, USA), unless otherwise stated.

In situ brain perfusion

Animals were anaesthetised as described above and given heparin (10,000 U/kg, i.p.) Following bilateral cannulation of the common carotid arteries, oxygenated Ringer solution (117 mmol/l NaCl, 4.7 mmol/l KCl, 0.8 mmol/l MgSO4, 24.8 mmol/l NaHCO3, 1.2 mmol/l KH2PO4, 2.5 mmol/l CaCl2,10 mmol/l d-glucose, 39 g/l 70-kDa dextran, 1 g/l bovine serum albumin and 0.055 g/l Evans Blue, heated to 37°C) was infused via a peristaltic pump. Once desired flow-rate and perfusion pressures (approximately 3 ml/min and 100 mmHg) were achieved, [14C]sucrose (370 kBq per 20 ml Ringer) was infused (0.5 ml/min per hemisphere) using a syringe pump for 5, 10, 15, or 20 min. At the end of the perfusion, samples of the perfusate were collected and the brain was removed. Cerebral hemispheres were stripped of meninges and choroid plexuses and homogenised by hand. Tissue and 100-μl samples of perfusate were thoroughly mixed with tissue solubiliser (TS-2; Research Products, Mount Pleasant, IL, USA) and incubated for 2 days. Samples were prepared for scintillation counting by the addition of 100 μl 30% acetic acid and 2.5 ml liquid scintillation cocktail (OptiPhase SuperMix; Perkin Elmer, Boston, MA, USA) and counted on a liquid scintillation counter (Microbeta Trilux; Perkin Elmer). Results are reported as the ratio of radioactivity in the brain to that in the perfusate (R br, μl/g):

$$ R_{{{\text{br}}}} = {\left( {{C_{{{\text{brain}}}} } \mathord{\left/ {\vphantom {{C_{{{\text{brain}}}} } {C_{{{\text{perfusate}}}} }}} \right. \kern-\nulldelimiterspace} {C_{{{\text{perfusate}}}} }} \right)} $$
(1)

where C brain is the radioactivity measured in brain (dpm/g) and C perfusate that in the perfusate (dpm/μl). In multi-timepoint uptake studies, unidirectional transfer coefficients (K in) were estimated for each group from the slope of a least-squares regression of R br vs perfusion time [21]:

$$ R_{{{\text{br}}}} {\left( t \right)} = V_{{\text{D}}} + K_{{{\text{in}}}} T $$
(2)

where V D is the initial volume of distribution of [14C]sucrose and T is the perfusion time (min).

Cerebral microvessel isolation

Cerebral microvessels were isolated from freshly removed brains as previously described [22]. For protein extraction, isolated microvessels were placed in 6 mol/l urea buffer (6 mol/l urea, 10 mmol/l Tris base, 1 mmol/l dithiothreitol, 5 mmol/l MgCl2, 5 mmol/l EGTA, 150 mmol/l NaCl, pH = 8.0, one tablet per 10 ml EDTA-free protease inhibitor [Complete Mini EDTA-free Protease Inhibitor; Roche, Mannheim, Germany]) and incubated at 4°C overnight. Protein was quantified using the bicinchoninic acid method (Pierce, Indianapolis, IL, USA) with BSA as a standard, and samples were frozen at −20°C for use within a week or at −80°C for use at a later time. For mRNA extraction, all isolation buffers were made in water treated with diethyl pyrocarbonate, microvessels were suspended in TRIZOL (Invitrogen, Carlsbad, CA, USA), and mRNA was isolated per manufacturer’s protocol and stored at −80°C until use.

Western blot

Protein samples (20 μg) were loaded on to 4 to 20% Tris-HCl gels (Ready Gels; Biorad, Hercules, CA, USA) and separated with 200 V for 30 min, followed by electrophoretic transfer to polyvinylidene difluoride membranes (240 mA, 45 min). Membranes were blocked overnight at 4°C in Tris-buffered saline (TBS) with 0.5% Tween-20 and 5% non-fat dry milk, then incubated in primary antibody overnight at 4°C. Membranes were washed several times with TBS-Tween-20-milk followed by TBS-Tween-20 without milk prior to incubation with HRP-conjugated secondary antibody for 45 min at room temperature, after which membranes were washed again, developed using enzyme chemiluminescence (ECLplus, Amersham), and visualised on X-ray film. Semiquantitation of scanned films was performed using Scion Image (Scion, Frederick, MD, USA), with gel staining (Gelcode; Pierce, Rockford, IL, USA) used to confirm consistency of protein loading. Results are reported as percent expression of control. Primary and secondary antibodies were diluted 1:2,000 in 0.5% BSA in PBS.

Real-time PCR

cDNA was synthesised using a kit (Superscript III First-Strand Synthesis SuperMix; Invitrogen) per manufacturer’s protocol and stored at −20°C until use. Real-time PCR was performed with a sequence detection system (RotorGene RG3000; Corbett Life Sciences, Sydney, Australia) and a Quantitect Sybr Green PCR Kit (Qiagen, Valencia, CA, USA). Primers (Electronic supplementary material [ESM] Table 1) were designed using Primer3 software [23]. cDNA was diluted to 8 ng/μl. The PCR reaction mixture contained 5 μl of Sybr master mix, 0.4 μl 25 mmol/l MgCl2, 0.35 μl RNAse-free water, 100 pmol of forward and reverse primers, and 16 ng cDNA in a volume of 10 μl. Reactions were performed in triplicate as previously described [24] at 95°C for 15 min; then 95°C for 15 s, 58°C for 15 s and 20 s at 72°C for 40 cycles, followed by a melt cycle consisting of stepwise increase in temperature from 72 to 99°C. Expression levels were calculated from cycle threshold numbers (threshold values) set within the exponential phase of the PCR normalised to endogenous cellular 18S RNA measured in parallel samples using 18S-specific primers.

Immunofluorescence microscopy

Animals were anaesthetised as described above. Following transcardiac perfusion with 0.9% saline, brains were removed and snap-frozen in 2-methyl butane with dry ice. Brains were stored at −80°C until cutting (minimum of 48 h). All slides were prepared with matched saline and streptozotocin samples on the same slides. Coronal sections (20 μm) from matched coordinates [25] were placed on to gelatine-coated slides and stored at −80°C until use. Immunofluorescence staining for tight junction proteins was performed on the basis of previously described methods [26]. Slides were brought to room temperature, air dried, fixed in 100% ethanol for 10 min, then washed in PBS followed by wash buffer (1% BSA–0.2% Tween-20 in PBS). After blocking 90 min in normal goat serum (Vector Labs, Burlingame, CA, USA) diluted 1:50 in wash buffer, slides were incubated overnight with primary antibody to tight junction proteins diluted 1:500 in wash buffer; incubation was in humidified chambers at 4°C. After rinsing with wash buffer, slides were incubated with appropriate fluorescent-tagged secondary antibody diluted 1:500 in wash buffer for 1 h at room temperature. Slides were rinsed with wash buffer and PBS and coverslips were mounted with Vectashield (Vector Labs). Microvessels were visualised on a laser scanning confocal microscope (Zeiss 510 Metaseries; Carl Zeiss Microimaging, Thornwood, NY, USA) with a 40× oil objective. Laser power, gain, pinhole, and all other image acquisition settings were maintained constant for image collection of matched saline and streptozotocin samples.

Fluorimetric gelatinase assay

Tail blood was collected as described above. After centrifugation (10,000 g, 5 min), plasma was decanted and stored at −20°C until use. Gelatinase activity was measured using a kit (EnzChek Gelatinase Assay; Molecular Probes). Plasma was diluted 1:2 in reaction buffer (50 mmol/l Tris-HCl, 150 mmol/l NaCl, 5 mmol/l CaCl2, 0.2 mmol/l NaN3, pH = 7.6), mixed with DQ-gelatin (1 mg/ml, final concentration) and incubated at 37°C. Fluorescence was measured (excitation: 485/20 nm, emission: 530/25 nm) with a fluorescence plate reader (FLx800; BioTek, Winooski, VT, USA) at various time points up to 180 min.

Gel zymography

Gel zymographic analysis was performed on plasma based on the methods of Asahi [27]. Plasma samples (0.5 μl) were run with molecular mass markers and recombinant MMP-2 and MMP-9 standards (Sigma) under non-reducing conditions (without â-mercaptoethanol or dithiothreitol) on 10% Tris-HCl gels containing 0.5% gelatin (Criterion; Biorad). Enzymes were renatured in the gel with 2.5% Triton X-100 in deionised water for 1 h at room temperature. Gels were then equilibrated in a digestion buffer (5 mmol/l CaCl2, 50 mmol/l Tris-HCl, pH 7.4, 200 mmol/l NaCl, and 0.2% Brij35) for 30 min at room temperature and then incubated for 24 h at 37°C in the same. Gels were stained with Brilliant Blue R (Biorad) for 1 h, followed by destaining in multiple washes with 5% methanol–7.5% acetic acid (until wash solution was clear, approximately 2 h), then photographed and analysed with a Kodak Image station; clear bands were indicative of gelatinolytic activity.

Statistical analysis

Student’s t test was used for comparison of two means, or in the case of more than two treatments, one-way ANOVA with a Tukey’s post hoc test was used. Linear regression coefficients were compared using the pooled estimate of variation around the regression lines to calculate T for comparison of K in and V D as previously described [28]. p < 0.05 was considered statistically significant for all comparisons.

Results

Streptozotocin treatment was associated with a significant attenuation of weight gain; by day 14 post-injection, streptozotocin-treated animals displayed significant elevations in blood glucose, cholesterol and triacylglycerol (Table 1).

Table 1 Blood chemistry and weight changes
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Permeability of the BBB to [14C]sucrose was measured by in situ brain perfusion (Fig. 1). K in for [14C]sucrose was 0.76 ± 0.18 μl g−1 min−1 in the saline group, which is comparable to previously reported measurements [22]. In the streptozotocin-treated group, K in was significantly (p = 0.018) increased to 1.83 ± 0.42 μl g−1 min−1, which coupled with the observation that V D was not significantly different (p = 0.242) between the two groups (saline = 4.76 ± 2.45 μl/g; streptozotocin = −2.16 ± 5.92 μl/g) indicates that streptozotocin treatment led to increased permeability of the BBB to [14C]sucrose.

Fig. 1
figure 1

In situ brain perfusion with [14C]sucrose. Values for the ratio of radioactivity in the brain to that in the perfusate (R br ) are mean ± SEM, n = 3–5 per time point. Closed markers, saline-treated; open markers, streptozotocin (STZ)-treated. STZ significantly (p < 0.05) increased the rate of [14C]sucrose entry into the brain (K in ) from 0.76 ± 0.18 to 1.83 ± 0.42 μl g−1 min−1, whereas the initial volume of distribution (V D ) for sucrose was not significantly different between the two groups (saline = 4.76 ± 2.45 μl/g; STZ = −2.16 ± 5.92 μl/g)

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To determine whether increased BBB permeability was the result of hyperglycaemia alone, we investigated the effect of long-term and acute alterations in blood glucose levels on sucrose distribution using single time point analysis [21]. Insulin treatment (8 U/kg twice daily) normalised blood glucose concentrations (9.3 ± 1.9 mmol/l) and attenuated increased brain distribution of sucrose following streptozotocin treatment (Fig. 2a). However, acute normalisation of plasma glucose with a single dose of insulin (15.7 ± 3.6 vs 29.3 ± 1.4 mmol/l in saline-treated controls, p < 0.01) had no statistically significant effect on sucrose distribution in streptozotocin-treated animals (Fig. 2b). In addition, acute hyperglycaemia (24.1 ± 3.6 vs 12.7 ± 1.8 mmol/l in saline-treated controls, p < 0.05) induced by i.v. injection of glucose did not increase brain distribution of sucrose (Fig. 2c). Scatter plotting of all individual data points in these experiments showed that there is no significant correlation (r = 0.1340) between plasma glucose concentration and brain distribution of sucrose, following acute modulation of glucose or insulin (Fig. 2d).

Fig. 2
figure 2

ad Effects of blood glucose modulation on brain distribution of [14C]sucrose. Data in all panels are from single time point (20-min) in situ brain perfusions with [14C]sucrose. Data (ac) are mean ratio of radioactivity in the brain to that in the perfusate (R br ) ± SEM, n = 46 per group. a Streptozotocin (STZ) significantly increased brain distribution of [14C]sucrose compared with saline (SAL). Long-term insulin (INS) treatment normalised blood glucose levels and attenuated this increase, with brain distribution of [14C]sucrose not significantly different from SAL or STZ. SAL, 14 days post saline injection; STZ, 14 days post STZ injection; STZ + INS, 14 days post STZ injection with insulin (8 U/kg, twice daily) begun on day 7. *p < 0.05, NS = not significantly different. Significance determined by one-way ANOVA with a Tukey’s post hoc test. b Acute normalisation of blood glucose with a single dose (8 U/kg) of insulin immediately prior to perfusion did not normalise brain distribution of sucrose in STZ-treated animals. STZ + SAL (SD), 14 days post STZ injection with a single dose of saline given prior to perfusion; STZ + INS (SD), 14 days post STZ injection with a single dose of insulin (8 U/kg) given prior to perfusion. c Acute hyperglycaemia induced by i.v. injection of a 50% glucose solution (GLU) did not increase brain distribution of [14C]sucrose compared with saline-injected controls. SAL (IV), injection of a 500-μl bolus of saline into the tail vein immediately prior to perfusion, GLU (IV), injection of a 500-μl bolus of 50% glucose solution into the tail vein immediately prior to perfusion. d Scatter plot of all individual data points summarised in other panels. Linear regression of points from the long-term insulin study (a, solid circles, solid line) indicates a significant correlation between blood glucose and brain distribution of [14C]sucrose (r = 0.4997, p < 0.05). Regression of points from acute modulation of glucose or insulin (b, c, open circles, dotted line) indicates no significant correlation between blood glucose concentration and brain distribution of [14C]sucrose (r = 0.1340, p > 0.50)

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In Western blot studies, all antibodies recognised bands at or near the expected molecular masses of each protein of interest (ZO-1, 220 kDa; occludin, 65 kDa; claudin-5, 22 kDa, Fig. 3b) in extracts from cerebral microvessels, as previously reported [22]. Expression of ZO-1 and occludin were significantly decreased to 58 ± 8 and 79 ± 6%, respectively, of saline-treated control levels in the streptozotocin group (Fig. 3a). Expression of claudin-5 was not significantly altered in streptozotocin-treated animals (Fig. 3a). Real-time-PCR analysis indicated that mRNA levels for these tight junction proteins were unaltered in streptozotocin-treated animals (ESM Table 1).

Fig. 3
figure 3

Summary of Western blot data. a Data are the summary of two blots for each protein, n = 3 unique samples per group per blot. Solid bars, saline-treated; open bars, streptozotocin-treated. Bars are mean percent expression of control ± SEM **p < 0.01. b Representative blots

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Brain slices stained for ZO-1, occludin and claudin-5 all showed distinct, continuous bands of staining in brain microvessels indicative of concentration of these proteins at the junctions of the endothelial cells (Fig. 4), as previously described [26]. No changes in junctional localisation were observed for ZO-1, occludin or claudin-5 following streptozotocin treatment; however, the staining intensity for both ZO-1 and occludin appeared to be reduced, consistent with Western blot data (Fig. 3).

Fig. 4
figure 4

Microscopy of BBB tight junction proteins. Coronal sections (20 μm) were stained for tight junction proteins. Saline (SAL) and streptozotocin (STZ) samples from matched stereotaxic coordinates were placed on the same slides, and all microscope settings were kept constant for all images acquired within a slide. Panels show representative sections from SAL and STZ frontal cortex; all regions (parietal, temporal, occipital, hippocampal and subcortical) showed the same pattern of results. Images are 40× in oil immersion. Scale bar on inset = 20 μm

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Gelatinolytic activity was measured in plasma using a fluorescence-based assay [29]. The rate at which DQ-gelatin was cleaved into fluorescent peptides was significantly increased in plasma from streptozotocin-treated animals (Fig. 5a,b). Gel zymography of plasma samples confirmed this finding, with a significant (p < 0.001) increase in gelatinolytic activity corresponding to the expected molecular mass of MMP-2 (72 kDa; Fig. 6).

Fig. 5
figure 5

Gelatinolytic activity in plasma. a Representative data from gelatinase activity assay in saline-treated (SAL, solid symbols) and streptozotocin-treated (STZ, open symbols) plasma. Data are relative fluorescence units (RFU) normalised to measurement at t = 0. b Summary of all gelatinase activity measurements in plasma. Data are mean of plot slopes as shown in (a)  ± SEM; n = 15 and 13 for SAL and STZ groups, respectively. *p < 0.05

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Fig. 6
figure 6

Gel zymographic analysis of MMP activity in plasma. a A representative zymogram (inverse image shown for clarity) of plasma samples from saline (SAL)-treated and streptozotocin (STZ)-treated animals with recombinant MMP-2 and MMP-9 included as standards. b Summary of data from three separate experiments. Data are mean relative optical density of the bands at ~72 kDa (MMP-2) ± SEM; n = 9 unique samples per group in total. ***p < 0.001

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Discussion

Streptozotocin injection is a well-established and robust model of type 1 diabetes that works by selectively killing the beta cells of the pancreas [30, 31]. Table 1 shows that classic symptoms of untreated diabetes (wasting, hyperglycaemia and hyperlipidaemia) were induced by streptozotocin, along with pronounced polyuria and polydipsia. By investigating BBB changes at a relatively early time point (14 days post-injection), we were able to focus on the onset and early progression of the disease, which is analogous to the period in humans when diabetes is most likely to go undiagnosed and therefore untreated [32], a critical period with regard to microvascular complications [33].

Previous studies of BBB permeability in animal models of diabetes have yielded variable results, with some investigators reporting increased permeability [9] and others no change [11, 12]. In this study, permeability of the BBB was measured by in situ brain perfusion, a highly sensitive method used to characterise movement of drugs into the brain [34] as well as changes in BBB permeability to tracer molecules with development [35], drugs [28], and disease [36]. The primary advantage of this approach is that the brain is isolated from the peripheral circulation, enabling complete control of tracer concentration and flow [34]. This is of particular importance in diabetes, as the elimination of many tracer molecules from the peripheral circulation is much more rapid than normal [37, 38]. Therefore, previous studies utilising peripheral infusion of tracers may have underestimated brain distributions of sucrose and mannitol in diabetic animals. In this study, streptozotocin treatment was associated with a 2.4-fold increase in the rate (K in) of [14C]sucrose entry into the brain without change in the initial volume of distribution (V D) (Fig. 1), indicating that the BBB is indeed compromised in this model of diabetes, and also confirming recent findings in diabetic patients [6, 8].

In a separate set of experiments, we showed that treatment with insulin begun on day 7 following streptozotocin injection normalised blood chemistry and attenuated the change in sucrose distribution (Fig. 2a). Interestingly, acute systemic hyperglycaemia in naïve animals had no significant effect on brain distribution of sucrose (Fig. 2b), nor did acute normalisation of blood glucose and insulin in streptozotocin-treated animals (Fig. 2c). Therefore, although BBB permeability changes do appear to occur downstream of hyperglycaemia in streptozotocin-induced diabetes, acute hyperglycaemia alone is not sufficient to induce the BBB changes observed in streptozotocin-treated rats. These data do not rule out the possibility that increased BBB permeability is the result of chronic hyperglycaemia and/or a chronic lack of insulin; indeed, the failure of acute normalisation of plasma glucose and insulin to restore BBB function in streptozotocin-treated animals (Fig. 2c) suggests that changes in BBB permeability in diabetes are time-dependent. Further study is warranted to illuminate the time-dependent and specific effects of insulin and chronic hyperglycaemia on BBB function. In addition, exposure of confluent primary rat cerebral endothelial cells to plasma from streptozotocin-treated animals leads to increased sucrose permeability compared with cells treated with plasma from control animals [39]. However, permeability of cells treated with plasma from control animals with hyperglycaemic levels of glucose added is not significantly different from controls [39], suggesting the presence of a soluble factor in diabetic plasma that regulates BBB permeability.

Increased distribution of a polar, water-soluble, non-transported molecule such as sucrose into the brain is indicative of increased paracellular diffusion at the BBB, a route normally blocked by tight junctions. Tight junctions are complexes of integral membrane proteins spanning intracellular clefts and cytoplasmic accessory proteins that link the transmembrane components to the actin cytoskeleton [40]. Changes in tight junction protein expression, posttranslational modification, subcellular localisation, and protein–protein interactions are associated with increased permeability [1]. A previous study indicated that streptozotocin-induced diabetes led to decreased protein expression of occludin, but not ZO-1, at the BBB [13]. In the present study, we observed decreased protein expression of both occludin and ZO-1 in cerebral microvessels of streptozotocin-treated rats, whereas claudin-5 expression remained constant (Figs. 3 and 4). This discrepancy might be explained by differences in tissue preparation. In the previous study, protein was taken from cortical homogenates, whereas we used an enriched preparation of cerebral microvessels. This is critical, as recently published work indicates that ZO-1 is expressed in neurons and glia as well as endothelial cells [41]. No changes were observed in mRNA levels for these tight junction proteins (ESM Table 1), suggesting that decreases in occludin and ZO-1 content are not due to transcriptional downregulation. Since occludin and ZO-1 are likely substrates for the MMP-2 and/or MMP-9 [20, 42], we investigated the possibility that gelatinase activity was upregulated in our streptozotocin-treated animals.

Plasma gelatinase activity was first measured by a fluorimetric assay (Fig. 5) in which proteolysis of a dye-quenched fluorescein-conjugated gelatin leads to liberation of fluorescent peptides. The rate of increase in fluorescent signal, therefore, was used to estimate the activity of MMP-2 and/or MMP-9 (Fig. 5). There was a statistically significant (p = 0.036) 46% increase in estimated gelatinase activity in plasma from streptozotocin-treated animals, which parallels recent findings in diabetic patient populations [16, 17, 43]. To determine the probable identity of the protease or proteases involved, gel zymographic analysis was performed on plasma samples (Fig. 6). Densitometric analysis indicated a small, but significant (p < 0.001) increase in gelatinolytic activity corresponding to 72 kDa, the expected molecular mass of MMP-2 (Fig. 6b). Interestingly, the MMP-9 standard used also showed proteolytic activity corresponding to this molecular mass as well as the expected molecular mass of 95 kDa for this enzyme; however, no activity corresponding to the expected molecular mass of MMP-9 was observed in our samples (Fig. 6a).

Visualisation of gelatinolytic activity in the brain by in situ zymography did not show any obvious changes associated with streptozotocin treatment (data not shown). This indicates that either changes in brain MMP activity with diabetes are too subtle or diffuse to be visualised by this technique, or that any increase in MMP activity is in fact limited to the peripheral circulation in this model. Increased MMP-9 levels in the peripheral circulation, but not in the brain itself, have also been associated with BBB leakage in a model of fulminant hepatic failure [44]. As the tight junction is located in the apical aspect of the interendothelial cleft [40], circulating MMPs would presumably have access to its extracellular components (e.g. occludin). A recent study found that occludin, but not claudin-5, was degraded by MMP-2 and MMP-9 in retinal endothelial cells, and that these MMPs were upregulated in streptozotocin-treated rats [15]. The present findings in diabetic brain are striking in their similarity, suggesting common pathophysiological mechanisms between the retinal and cerebral microvasculature.

In this study, we also observed a significant dyslipidaemia, with elevated cholesterol and triacylglycerol (Table 1). A recent study [9] indicated that statins have an ameliorating effect on cerebral endothelial changes induced by streptozotocin, indicating that hyperlipidaemia may also play a role. There is also evidence that statins can downregulate MMP-2 and MMP-9 activity independently of lipid modulation [45, 46], which, in light of the present finding of increased gelatinase activity in streptozotocin-treated rats, may also account for the protective effect of statins on the BBB. Another possibility that cannot be ruled out is that changes in BBB permeability occur secondary to peripheral inflammation in response to streptozotocin [47, 48]. Further studies are warranted to clarify the possible interactions between MMP activity, hyperlipidaemia, inflammation, and BBB function.

In conclusion, we have demonstrated that streptozotocin-induced diabetes leads to increased BBB permeability, that acute hyperglycaemia is not sufficient to induce this change, and that this change is associated with specific alterations in tight junction proteins. This indicates that microvascular complications similar to those affecting peripheral organs in diabetes may have a deleterious effect on the central nervous system, as well, and that glucose management alone may be insufficient for their prevention [6]. Compromise of BBB paracellular permeability along with alterations in BBB transport [49, 50] may present a link between diabetes and neurological complications associated with the disease. Finally, we have demonstrated that experimental diabetes is associated with increased gelatinolytic (MMP-2 and/or MMP-9) activity in the blood. The changes observed in this study are similar to those reported for both BBB permeability [6] and blood MMP activity [16, 17] in diabetic patients, suggesting that circulating MMPs are a potential target for prevention of neurovascular and neurological complications in diabetes.