2.1.

Brain Cell and Tissue Samples Preparation

All animal experiments were performed following the protocol approved by the University of Tennessee Health Science Center (UTHSC) Institutional Animal Care and Use Committee (IACUC). Mice were housed in groups of 3 to 5 per cage, segregated by sex, in a room on a 12 h/12 h light/dark cycle (lights on at 8:00 AM and off at 8:00 PM) maintained at $22\pm 2°\mathrm{C}$. Pregnant mice for 6 weeks were fed with ethanol (0% 2 days, 1% 2 days, 2% 2 days, 4% 1 week, and 5% 1 week) in Lieber-DeCarli liquid diet (EF). The control group was pair fed with an isocaloric diet. Brain sections from the control or pair fed (PF) and ethanol fed (EF) offspring were collected at 60-days postnatal age and cryofixed for fluorescence staining using confocal microscopy. While the offspring of PF and EF mice were excised and the brain tissue sections from the frontal cortex region were cryofixed and sectioned into a thickness of $10\mu \mathrm{m}$ using microtome for the PWS and IPR analyses.

2.2.

Partial Wave Spectroscopy for Structural Disorder Detection

2.3.

Confocal Microscopy for DNA/Histone Spatial Molecular Mass Density Structural Disorder Detection

3.1.

Partial Wave Spectroscopy Study of Brain Tissues

The light scattering, PWS technique and molecular-specific light localization, confocal-IPR technique were used to detect the nano-to-submicron scale structural alterations in the mice pup brain tissue and nuclei due to fetal alcoholism. For this, the PWS analysis was performed in the paraffin-embedded $10\text{-}\mu \mathrm{m}$ thick on the PF and EF mice pup brain tissue sections, and the degree of structural disorder strength, $L_{\mathrm{d}\text{-}\mathrm{PWS}}$, was calculated as mentioned in Sec. 2.2. These pup brain cells/tissues were collected at postnatal day 60 to quantify their structural properties due to exposition to fetal alcoholism. Then, using the confocal-IPR analysis, the average IPR, $⟨\mathrm{IPR}⟩$ value was calculated at sample length $L=0.8\mu \mathrm{m}$ to study the effect of alcohol in EF mice pup brain cell nuclei, especially in the DNA and histone for all the categories as explained in Sec. 2.3. Here, the IPR study was performed and compared between (i) PF DAPI-stained brain cells and EF DAPI-stained brain cells and (ii) PF H3K27me3-stained brain cells and EF H3K27me3-stained brain cells.

Figures 1(a)–1(b) and 1(a′)–1(b′) represent the bright field images and $L_{\mathrm{d}\text{-}\mathrm{PWS}}$ images, respectively, of PF and EF mice pup thin brain tissue from frontal cortex sections. Based on quasi-1D approximation in PWS, the samples were virtually divided into several parallel channels, and the backscattered signals propagating along 1D trajectories were collected to calculate the degree of structural disorder strength ($L_{\mathrm{d}\text{-}\mathrm{PWS}}$) at every pixel position. This disorder strength is calculated in terms of the refractive index fluctuations is represented in a 2D color map of the $L_{\mathrm{d}\text{-}\mathrm{PWS}}$ image in Fig. 1(c), where the red color represents the higher refractive index fluctuations present in the tissue section averaged along the $z$-axis. Although the bright field images look similar, the $L_d$ images show that the EF pup brain tissue structure has more red spots indicating a higher degree of refractive index fluctuations or the disorder strength than the PF pup. This is due to the alcohol effect in the fetus of alcoholic mothers’ pups. Further, the average disorder strength ($L_{\mathrm{d}\text{-}\mathrm{PWS}}$) was calculated and represented in Fig. 1(c). The PWS quantification shows that the average degree of disorder strength of EF mice pup brain tissue increases significantly by 26% compared to the PF pup. This increase in the degree of disorder strength of EF pup brain tissue structure is due to the adverse effects of alcohol in the brain of pups, as a result of alcohol consumption by the mother during her pregnancy. Since alcohol consumed during pregnancy is equally consumed by the fetus may result in different neurological abnormalities in the newborn. It is found that alcohol affects the different brain cells, such as astrocytes, microglia, etc. including cell components such as chromatin, histone, etc. which are initially at the nanoscale level eventually leading to brain malfunctioning. FAS and alcohol-related neurodevelopmental disorders in newborn infants are the long-term outcomes of fetal alcoholism. This quantitative approach to the measurement of such structural alterations in the brain tissue due to fetal alcohol exposure (FAE) using the PWS technique provides a better understanding of the structural properties at the earliest stages of fetal alcoholism to employ better treatment modalities.

Fig. 1

Brain tissue structural disorder using PWS: (a)–(b) the bright field images of PF and EF mice pup brain tissue while (a′)–(b′) their respective $L_{\mathrm{d}\text{-}\mathrm{PWS}}$ images, which are distinct than the bright field images. (c) The EF mice pup’s brain tissues have a higher degree of the average disorder strength, $L_{\mathrm{d}\text{-}\mathrm{PWS}}$ than PF pups. The average $L_{\mathrm{d}\text{-}\mathrm{PWS}}$ of EF mice pup brain tissue increases by 26% in reference to the PF pups. (Student $t$-test, $P\text{-}\text{value}<0.05$, PF mice ($n=5$) and EF mice ($n=5$), 3 to 5 samples per mouse).

3.2.

Confocal-IPR Study of: (i) DNA Molecular-Specific DAPI Staining and (ii) Histone Molecular-Specific H3K27me3 Staining

Figures 2(a)–2(b) show the DAPI-stained mice pup brain cells for PF and EF, respectively, and 2(a′)–2(b′) are the corresponding $⟨\mathrm{IPR}⟩$ images of these cells. DAPI staining mainly targets DNA molecules in the brain cell nuclei. Figure 2(c) shows the bar graph comparison of ensemble $⟨\mathrm{IPR}⟩$ values at the sample length $L=0.8\mu \mathrm{m}$ of PF and EF DAPI-stained pup brain molecules. The result shows the higher $⟨\mathrm{IPR}⟩$ value or disorder strength ($L_{\mathrm{d}\text{-}\mathrm{IPR}}$) for EF pup brain cells, indicating higher structural disorder than the PF pup brain cells. This result suggests that the $⟨\mathrm{IPR}⟩$ value of DNA increased due to fetal alcoholism. This is due to an increase in the mean mass density fluctuation in DNA/chromatin of alcoholic mice pup brain cell nuclei. Figures 3(a)–3(b) represent the H3K27me3 antibody-stained pup brain cells for the PF and EF, respectively, while 3(a′)–3(b′) are their corresponding $⟨\mathrm{IPR}⟩$ images. H3K27me3 antibody staining mainly targets the histone molecules in the brain cell nuclei. Figure 3(c) shows the bar graph comparison of the ensemble $⟨\mathrm{IPR}⟩$ values for PF H3K27me3-stained and EF H3K27me3-stained pup brain cells. The graphs show histone structures in pup brain cells exposed to fetal alcoholism has less $⟨\mathrm{IPR}⟩$ or structural disorder relative to the PF pup. This, the opposite trend of the nuclear DNA molecular structure, shows an interesting result as an adverse effect of fetal alcoholism.

Fig. 2

DNA molecular-specific structural disorder by confocal-IPR. (a)–(b) The confocal images of the PF and EF DAPI-stained pup brain cells while (a′)–(b′) are their respective IPR images. (c) The $⟨\mathrm{IPR}⟩\sim L_{\mathrm{d}\text{-}\mathrm{IPR}}$ values for PF DAPI-stained and EF DAPI-stained pup brain cells at sample length $L=0.8\mu \mathrm{m}$ are presented. The $⟨\mathrm{IPR}⟩$ value for EF DAPI-stained brain cells was found to be higher compared to that of PF DAPI-stained brain cells. As DAPI binds with DNA molecules, the above bar plots show that EF pups have more structural disorder in their brain cell nuclei leading to different kinds of abnormalities. The percentage difference between the $⟨\mathrm{IPR}⟩$ values of these two groups is 14%. (Student $t$-test, $P\text{-}\text{value}<0.05$, PF mice ($n=5$) and EF mice ($n=5$), 3 to 5 samples per mouse).

Fig. 3

Histone molecular-specific structural disorder by confocal-IPR: (a)–(b) the confocal images of the PF and EF H3K27me3-stained pup brain cells targeting histone, and (a′)–(b′) represent their respective $⟨\mathrm{IPR}⟩$ images. (c) The $⟨\mathrm{IPR}⟩$ values or the degree of structural disorder at sample length $L=0.8\mu \mathrm{m}$ for PF H3K27me3-stained and EF H3K27me3-stained pup brain cells are presented. The $⟨\mathrm{IPR}⟩$ value for PF H3K27me3-stained brain cells was found to be lower compared to that of the PF H3K27me3-stained brain cells. The percentage difference of the $⟨\mathrm{IPR}⟩$ values for structural disorder between these two groups is 10%. (Student t-test, $P\text{-}\text{value}<0.05$ PF mice ($n=5$) and EF mice ($n=5$), 3 to 5 samples per mouse.)

The $⟨\mathrm{IPR}⟩$ values at the sample length $L=0.8\mu \mathrm{m}$ targeting DNA molecules of EF pup brain cells nuclei are found to be higher than the PF pup. This $⟨\mathrm{IPR}⟩$ value is correlated with the structural abnormalities, which indicates that the spatial mass distributions or fluctuations of DNA molecules in an EF pup’s brain cells are higher. The introduction of alcohol during pregnancy is consumed by the fetus and results in spatial variation in the components of DNA at the nanoscale level and hence is responsible for the changes in genetics and results in different fetal alcoholic syndromes.

However, the $⟨\mathrm{IPR}⟩$ value of EF H3K27me3 antibody-stained brain cells targeting histone is found to be less than the $⟨\mathrm{IPR}⟩$ value of PF H3K27me3-stained pup brain cells at sample length $L=0.8\mu \mathrm{m}$. This suggests that the mass density fluctuations decrease in EF H3K27me3-stained pup’s stained brain cells compared to the PF pup suggesting some effect of alcohol in histone molecular mass density. And, this decrease in mass density fluctuations in the histone proteins of brain cells due to fetal alcoholic exposition concludes suppression in certain gene expression resulting in FAS.

3.3.

Quantitative RT-PCR Study for Measure the DNA Damage to Support the Structural Disorder

3.3.1.

Quantitative RT-PCR method

Here, we quantify the amount of DNA damage using a quantitative RT-PCR study. Total RNA ($1.5\mu \mathrm{g}$) was used for the generation of cDNAs using the ThermoScript RT-PCR system for first strand synthesis (Invitrogen, Carlsbad, California). Quantitative PCR (qPCR) reactions were performed using cDNA mix (cDNA corresponding to 35 ng RNA) with 300 nmol of primers in a final volume of $25\mu \mathrm{L}$ of $\times 2$ concentrated RT2 real-time SYBR Green/ROX master mix (Qiagen, Venlo, the Netherlands) in an Applied Biosystems 7300 real-time PCR instrument (Norwalk, Connecticut). The cycle parameters were 50°C for 2 min, one denaturation step at 95°C for 10 min, and 40 cycles of denaturation at 95°C for 10 s followed by annealing and elongation at 60°C. Relative gene expression of each transcript was normalized to GAPDH using the $\mathrm{\Delta }\mathrm{\Delta }\mathrm{Ct}$ method.³¹ Sequences of primers used for qPCR are provided in Table 1.

Table 1

Sequences of primers used for qPCR experiment.

γH2AX

Forward primer: AACGACGAGGAGCTCAACAAGC

Reverse primer: TGGCGCTGCTCTTCTTGGGCA

GAPDH

Forward primer: CTGCACCACCAACTGCTTAG

Reverse primer: GGGCCATCCACAGTCTTCT

Expression of DNA damage marker gene was analyzed by measuring the specific mRNA levels in the frontal cortex. Levels of mRNA for γH2AX were significantly increased in litters of EF dams compared to those in the litters of PF dams at postnatal day 60, as shown in Fig. 4.

Fig. 4

FAE litters showed DNA damage marker gene (γH2AX) expression changes in the frontal cortex. Relative quantification measured by real-time RT-PCR indicates an increase in γH2AX transcript levels in the frontal cortex of adult litters of EtOH consuming mother.³¹ Asterisk indicates the value that is significantly different from corresponding control value (Student’s $t$-test, $P\text{-}\text{value}<0.05$, PF mice ($n=5$) and EF mice ($n=5$), 3 to 5 samples per mouse).

4.1.

Quantitative RT-PCR Experiment Supports an Increase in the Structural Disorder by DNA Damage

Specific mRNA levels in the frontal cortex were quantified by measuring the expression of the DNA damage marker gene. Results show that the levels of mRNA for $\gamma \mathrm{H}2\mathrm{AX}$ were significantly increased in litters of EF dams compared to those in the litters of PF dams at postnatal day 60. It is known that molecular-level damage increases the spatial disorder in a system. Therefore, an increase in DNA damage supports the increase in the IPR (or $L_{\mathrm{d}\text{-}\mathrm{IPR}}$) value that measures the increase in the spatial structural disorder, or spatial disorder strength, of the spatial molecular mass density.

4.2.

Plausible Reasons for an Opposite Change in the $⟨\mathrm{IPR}⟩\sim L_{\mathrm{d}\text{-}\mathrm{IPR}}$ of DNA and Histone Molecules

Fetal alcoholism or alcohol consumed by the fetus might have caused the histone protein modifications, which in turn could be responsible for enhancing the relaxation of chromatin, causing lower mass density fluctuations and hence a smaller $⟨\mathrm{IPR}⟩$ value. H3K27me3 antibody is the trimethylation of lysine 27 on a histone protein, and the addition of alcohol causes the loss of the H3K27me3 methylation process. This loss of methylation may have played a role in DNA unwinding and gene expression. This decrease in the $⟨\mathrm{IPR}⟩$ value or disorder strength is due to the loss of methylation from the loosely attached histones but not from the tightly attached histone to the DNA. Furthermore, fetal alcoholism could result in the loose holding of nucleosomes, which causes a more relaxed state of chromatin. The relaxed state of chromatin increases the homogeneity in histone, reducing the mass density fluctuation or refractive index fluctuation. Therefore, we can conclude that alcohol consumed by a pregnant mother is consumed by the fetus which results in the upregulation or downregulation in the expression of certain gene types in pup brain cell nuclei could have resulted in FAS disorder or other neurological abnormalities.

In summary, we probed the structural changes in tissue, and spatial molecular specific DNA and histone of mice pups’ brains, which are initially at the nanoscale level, exposed to fetal alcoholism. Preliminary results are promising, and this invites a detailed study to interconnect these results and explain how they are related to long-term brain abnormalities.