Article

ISSN 0006-2979, Biochemistry (Moscow), 2024, Vol. 89, No. 5, pp. 904-911 © Pleiades Publishing, Ltd., 2024.

904

Microglia and Dendritic Cells as a Source of IL-6

in a Mouse Model of Multiple Sclerosis

Violetta S. Gogoleva

1,a

*, Quynh Chi Nguyen

, and Marina S. Drutskaya

Center for Precision Genome Editing and Genetic Technologies for Biomedicine,

Engelhardt Institute of Molecular Biology, Russian Academy of Sciences, 117997 Moscow, Russia

Faculty of Biology, Lomonosov Moscow State University, 119991 Moscow, Russia

e-mail: violettegogoleva@mail.ru

Received December 6, 2023

Revised February 1, 2024

Accepted February 6, 2024

Abstract— Multiple sclerosis (MS) is a complex autoimmune disease of central nervous system (CNS) character-

ized by the myelin sheath destruction and compromised nerve signal transmission. Understanding molecular

mechanisms driving MS development is critical due to its early onset, chronic course, and therapeutic approaches

based only on symptomatic treatment. Cytokines are known to play a pivotal role in the MS pathogenesis with

interleukin-6 (IL-6) being one of the key mediators. This study investigates contribution of IL-6 produced by mi-

croglia and dendritic cells to the development of experimental autoimmune encephalomyelitis (EAE), a widely

used mouse model of MS. Mice with conditional inactivation of IL-6 in the CX

CR1

cells, including microglia, or

CD11c

dendritic cells, displayed less severe symptoms as compared to their wild-type counterparts. Mice with

microglial IL-6 deletion exhibited an elevated proportion of regulatory T cells and reduced percentage of patho-

genic IFNγ-producing CD4

T cells, accompanied by the decrease in pro-inflammatory monocytes in the CNS at

the peak of EAE. At the same time, deletion of IL-6 from microglia resulted in the increase of CCR6

T cells and

GM-CSF-producing T cells. Conversely, mice with IL-6 deficiency in the dendritic cells showed not only the previ-

ously described increase in the proportion of regulatory T cells and decrease in the proportion of T

17 cells, but

also reduction in the production of GM-CSF and IFNγ in the secondary lymphoid organs. In summary, IL-6 func-

tions during EAE depend on both the source and localization of immune response: the microglial IL-6 exerts both

pathogenic and protective functions specifically in the CNS, whereas the dendritic cell-derived IL-6, in addition to

being critically involved in the balance of regulatory T cells and T

17 cells, may stimulate production of cytokines

associated with pathogenic functions of T cells.

DOI: 10.1134/S0006297924050109

Keywords: interleukin-6, microglia, dendritic cells, experimental autoimmune encephalomyelitis, multiple

sclerosis, mouse models

Abbreviations: ΔDC, gene deletion only in dendritic cells; ΔMG, gene deletion only in microglia; BBB,blood-brain barrier;

CNS, central nervous system; EAE, experimental autoimmune encephalomyelitis; IL, interleukin; MS, multiple sclerosis;

,Thelper cells; T

reg

,regulatory T cells.

* To whom correspondence should be addressed.

INTRODUCTION

Multiple sclerosis (MS) is a chronic autoimmune

disease that affects the central nervous system (CNS)

and causes severe consequences, including visual dis-

turbances, motor and cognitive impairments. In recent

years, there has been an increasing trend in the

number of people diagnosed with MS, however, only

symptomatic treatments aimed at modulating the

symptoms are currently available [1]. Therefore, the

search for new therapeutic targets remains a very

important task. One of the most widely used experi-

mental models of MS in mice is experimental autoim-

mune encephalomyelitis (EAE) [2]. Pathogenesis of

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BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

EAE primarily involves the activation of CD4

T  cells,

followed by their differentiation, and infiltration into

the CNS in response to immunization with antigens

from the myelin sheath of neurons in complete Fre-

und’s adjuvant [3]. Cytokines, including IL-6, play a

crucial role in EAE pathogenesis. In particular, it has

been shown that pharmacological and genetic inacti-

vation of IL-6 in the mouse model of multiple sclerosis

leads to a reduction in disease severity [4] or absolute

resistance [5].

It has been established that the pathogenic role

of IL-6 is realized via various mechanisms involved in

the regulation of blood-brain barrier (BBB) permea-

bility and the development of CD4

T  cell subsets. Im-

munization of wild-type mice with the myelin peptide

MOG

35-55

was shown to increase the expression of ad-

hesion molecules such as VCAM-1 and ICAM-1 on the

surface of endothelial cells in the BBB as compared to

IL-6-deficient mice [5]. It is known that activation of

two subunits of the IL-6 receptor complex, IL-6Rα and

gp130, is required for IL-6 signal transduction. It has

been shown that trans-presentation of IL-6 (trans-

duction of an intracellular signal by interaction of

IL-6R–IL-6 on the surface of one cell with gp130 on the

surface of another) is necessary for the polarization

of pathogenic T  helper cells producing IL-17A (T

cells) in the EAE model [6]. This has been confirmed

by the fact that deletion of gp130 from the surface of

T  cells suppresses the differentiation of CD4

 T  cells

into FoxP3

regulatory T  cells (T

reg

), thus facilitating

the development of RORγt

17 cells [7]. Remarkably,

there is a positive feedback between IL-6 and IL-17A

produced by pathogenic T

17 cells: IL-17A stimulates

IL-6 production by astrocytes, which further facilitates

17 polarization [8,9].

The main sources of IL-6 in the CNS are various

cells of non-immune origin, in particular, neurons,

astrocytes, and endothelial cells [10], but in the EAE

model the main source of IL-6 are myeloid cells [6],

including dendritic cells and microglia (resident mac-

rophages of the CNS), in particular. Although there is a

large amount of data supporting various functions of

IL-6 in the EAE model, the characteristics of cytokine

production by T cells over the course of disease patho-

genesis with respect to the specific subpopulations of

myeloid cells have not been investigated in sufficient

detail, which was the aim of this study.

MATERIALS AND METHODS

Mice. Cd11c

Cre

 × Il6

fl/fl

(mice with Il6 deletion pre-

dominantly in dendritic cells) [11] and Cx3cr1

CreER

 × Il6

fl/fl

(mice with Il6 deletion in CX

CR1

myeloid cells, includ-

ing microglia). Il6

fl/fl

mice [12] were crossed to Cx3cr1

CreER

mice [13] to generate mice with Il6 deletion in CX

CR1

myeloid cells. Both male and female mice aged 9 to 12

weeks were used. Mice were bred and housed in SPF

conditions at the Animal Facility of the Institute of Cy-

tology and Genetics, Siberian Branch of the Russian

Academy of Sciences and at the Animal Facility of the

Center for Precision Editing and Genetic Technologies

for Biomedicine, Engelhardt Institute of Molecular Bi-

ology, Russian Academy of Sciences [EIMB RAS] (un-

der the contract #075-15-2019-1660 from the Ministry

of Science and Higher Education of the Russian Fed-

eration). All manipulations with animals were carried

out in accordance with the protocol approved by the

Bioethics Committee of the EIMB RAS (Protocol No. 3

from 21/09/2023).

Tamoxifen treatment. Tamoxifen (Sigma Aldrich,

USA) was dissolved in corn oil (Sigma Aldrich) to a

concentration of 15 mg/ml by prolonged incubation

with continuous shaking on a thermoshaker at 37°C

overnight and protected from light. Two ml aliquots

of the obtained solution were placed into tubes and

stored at 4°C for 5days. To induce IL-6 deletion in mi-

croglia, 8-9-week-old Cx3cr1

CreER

×Il6

fl/fl

mice and con-

trol Il6

fl/fl

mice were injected intraperitoneally daily

with 100  µl of tamoxifen solution at a dose of 75 mg/kg

for 5 days.

EAE induction. Mice were subcutaneously im-

munized with 100 µg of MOG

35-55

-peptide (myelin oli-

godendrocyte glycoprotein; Anaspec, USA) in complete

Freund’s adjuvant (Sigma Aldrich) supplemented with

5  mg/ml of inactivated Mycobacterium tuberculosis

(Difco, USA), followed by intraperitoneal injections of

200  ng Pertussis toxin (Sigma Aldrich) on days 0 and

2 to increase BBB permeability. EAE clinical scores

were defined as follows: 0 – no disease; 0.5 – partial

tail paralysis; 1– complete tail paralysis; 1.5– partially

impaired righting reflex; 2– impaired righting reflex;

3–hind limbs paresis; 3.5– complete paralysis of hind

limbs; 4 – forelimbs paresis; 4.5 – complete paralysis

of forelimbs.

Cell isolation. For isolation of blood mononu-

clear cells, peripheral blood was collected in tubes

with heparin and centrifuged (without acceleration

or brakes) in a Ficoll density gradient for 30 min

(1.077  g/cm

, PanEko, Russia). Single cell suspensions

of spleen and lymph nodes were prepared by mechan-

ical dissociation through 70  µm filter (NEST, China) in

PBS supplemented with 2%  FBS. Red blood cells were

lysed in ACK buffer (1.5 M  NH

Cl; 100  mM KHCO

;

10  mM  EDTA-2Na in distilled water, pH  7.2). Immune

cells from the CNS were isolated according to the pro-

tocol [14]. Briefly, mice were anesthetized and tran-

scardially perfused using 0.9%  NaCl solution. Spinal

cord and brain were removed, mechanically dissoci-

ated, and digested enzymatically in DPBS containing

1.5  mg/ml collagenase  II (Gibco) and 50  µg/ml DNAse  I

(Roche, Switzerland). Cells were homogenized using

GOGOLEVA et al.906

BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

the syringe with 18G  ×  1.5′′ needle and washed in PBS

supplemented with 2%  FBS. Next, fractions of immune

cells were separated by centrifugation (500g, 25°C,

40  min, (without acceleration or brakes) in a Percoll

density gradient (30/37/70, GE Healthcare, USA).

Flow cytometry analysis. For intracellular cyto-

kine staining, single cell suspensions prepared from

spleen or lymph nodes were stimulated with phor-

bol-12-myristate-13-acetate (PMA; Sigma Aldrich),

500  ng/ml of ionomycin (Sigma Aldrich) for 4 h, 37°C,

5%  CO

in the presence of 3  mg/ml of Brefeldin  A

(eBioscience, USA). To prevent non-specific binding

of antibodies, single cell suspensions were incubated

for 20  min at 4°C with purified anti-mouse CD16/CD32

(clone 2.4G2, in-house DRFZ collection), washed and

stained with following antibodies: anti-CD45 (clone30-

F11, BioLegend, USA), anti-CD11b (cloneM1/70, BioLeg-

end), anti-Ly6C (clone HK1.4, Invitrogen, USA), anti-

MHCII (clone M5/114.15.2, BioLegend), anti-CX

CR1

(clone SA011F11, BioLegend), anti-CD4 (clone RM4-5,

BioLegend), anti-TCRb (clone H57-597, eBioscience),

anti-IFNγ (clone XMG1.2, Biolegend), anti-IL-17A

(cloneeBio17B7, BioLegend), anti-GM-CSF (cloneMP1-

22E9, BioLegend), anti-FoxP3 (clone FJK-16s, Invitro-

gen), anti-RORγt (clone B2D, Invitrogen). Dead cell

exclusion was performed by using a Fixable Viabil-

ity Dye (eBioscience). Samples were acquired with

BD FACSCanto II or BDFACSAria III (Beckton Dick-

inson, USA). CD45

CD4

–

CR1

blood monocytes or

CD45

CD11b

CR1

microglia were sorted using a

BDFACSAriaIII with a purity of >90%. Data were ana-

lyzed using FlowJo Software (Beckton Dickinson).

ELISA. Sorted monocytes and microglia were

activated with lipopolysaccharide (LPS form E.  coli

O111:B4, Sigma [100  ng/ml] for 4  h). IL-6 concentra-

tion in supernatant was determined using mouse IL-6

ELISA Ready-SET-Go! kit (eBioscience) according to

manufacturer’s instructions.

Statistical analysis. Statistical analysis was per-

formed using GraphPad Prism 9. All the data were

analyzed using unpaired Student’s t-test or one-way

ANOVA. Differences were considered significant when

p-values were<0.05.

RESULTS AND DISCUSSION

Myeloid cell-derived IL-6 plays a critical role in

the pathogenesis of EAE. To investigate role of IL-6

produced by myeloid cells in EAE development mice

with IL-6 deletion either (i)  only in dendritic cells

(Il6

ΔDC

), or (ii)  only in microglia (Il6

ΔMG

) were used.

Littermate Il6

fl/fl

were used as control mice in all ex-

periments. Mice with IL-6 deletion in dendritic cells

have been previously generated and are character-

ized by constitutive inactivation of IL-6 in the CD11c

cells [11,15]. Mice with IL-6 deletion in microglia were

generated by crossing Cx3cr1

CreER

mice, which express

tamoxifen-dependent Cre-recombinase under the con-

trol of the CX

CR1 promoter [13], to mice with the

floxed Il6 gene (Il6

fl/fl

) [12]. The principle of this system

is the cell-specific inactivation of the Il6 gene flanked

by loxP-sites (floxed) by Cre-recombinase fused with

the mutant form of the estrogen receptor only in the

CR1

cells in response to the administration of

tamoxifen (Fig.1a).

For tissue-specific inactivation of IL-6 exclusive-

ly in microglia, Cx3cr1

CreER

×Il6

fl/fl

and wild type mice

(Il6

fl/fl

) were injected with tamoxifen at a dose of

75µg/g for 5 days; 14days after tamoxifen administra-

tion, IL-6 deletion occurred both in monocytes (Fig.1b)

and dendritic cells, as well as in microglia [13]. After

complete repopulation of CX

CR1

myeloid cells from

the bone marrow, i.e., 28 days after tamoxifen admin-

istration, mice retained IL-6 deletion only in the pop-

ulation of long-lived tissue-resident macrophages, in-

cluding microglia (Fig.1c).

EAE was induced by immunization with the

MOG

35-55

-peptide in complete Freund’s adjuvant, fol-

lowed by injection of Pertussis toxin to increase BBB

permeability. Clinical signs were assessed starting day

8 after immunization. Mice with IL-6 deficiency only

in microglia or only in dendritic cells developed mild-

er disease symptoms as compared to wild-type mice

(Fig. 1d). These results are consistent with previous

observations indicating that exactly dendritic cells [6]

and microglia [16] are critical sources of IL-6 in the

EAE model.

Microglia-derived IL-6 regulates immune re-

sponse in the CNS at the peak of EAE. Given that mi-

croglia are tissue-resident macrophages in the CNS, it

was hypothesized that the functions mediated by these

cells would mainly affect the immune response in the

CNS. Therefore, on day 16 after immunization (effector

phase of the disease), the frequency of myeloid cells

and antigen-specific CD4

T cells in the CNS was as-

sessed by flow cytometry. Mice with IL-6 inactivation

in microglia showed a reduced frequency (Fig.2a) and

absolute number (Fig.2b) of Ly6C

MHCII

monocytes,

which play an exclusively pathogenic role in EAE.

Additionally, there was a decrease in the percentage

of IFNγ-producing CD4

T cells (Fig. 2c). These results

are consistent with each other, as it is precisely IFNγ

that supports differentiation of the Ly6C

-monocytes

into MHCII

effector dendritic cells [17]. At the same

time, these findings are consistent with the previously

published data on the stimulation of T

reg

development

(Fig.2d) at low concentrations of IFNγ[18].

As shown in the current study, mice with microg-

lial IL-6 deletion develop milder EAE symptoms as

compared to wild-type mice, yet, they do not exhibit

complete resistance to disease development (Fig. 1d).

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BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

Fig. 1. Mice with tamoxifen-dependent inactivation of IL-6 in CX

CR1

microglia are hyposusceptible to EAE induction. a)Scheme

of experiment. Mice were administered Tamoxifen (75µg/g) i.p. for 5 consecutive days. At 7-14 days after Tamoxifen injec-

tions, IL-6 deletion was detected in both tissue-resident macrophages and monocytes, but after 28 days, replenishment of the

monocyte pool from the bone marrow occurred and IL-6 deficiency was observed only in tissue-resident macrophages includ-

ing microglia; b)concentration of IL-6 in the supernatant of sorted CX

CR1

monocytes isolated from the peripheral blood of

Cx3cr1

CreER

×Il6

fl/fl

mice on days 0, 14, 28after Tamoxifen administration and activated with LPS for 4 h; ND – not detected;

c)concentration of IL-6 in the supernatant of sorted CX

CR1

microglia isolated from the CNS of Cx3cr1

CreER

×Il6

fl/fl

mice on day

28 after Tamoxifen administration and activated with LPS for 4h; d)Clinical disease course of MOG

35-55

emulsified in complete

Freund’s adjuvant-induced EAE in wild-type mice (Il6

fl/fl

), mice with IL-6 deletion in microglia (Il6

ΔMG

), and mice with IL-6 de-

letion in dendritic cells (Il6

ΔDC

). Data are shown as mean ±SEM and are representative of three independent experiments with

four or more mice per group in each experiment.

Moreover, these mice show an increase in the per-

centage of T

reg

, that suppress the development of EAE

(Fig.2d), suggesting the presence of an additional com-

ponent that contributes to the manifestation of clini-

cal symptoms. We hypothesized that these mice may

demonstrate an increase in the infiltration of patho-

genic T cells into the CNS. The CCR6/CCL20 axis is cru-

cial for the migration of immune cells into the CNS

and is particularly important for the initial wave of

T cell infiltration into the CNS [19]. Indeed, mice with

IL-6 deletion in microglia exhibited an increase in the

frequency of CCR6

T cells in the CNS (Fig.  3a). Fur-

thermore, these mice showed an increased percent-

age of GM-CSF-producing, but not IL-17A- producing,

CD4

 T cells (Fig.  3b). GM-CSF production by T cells is

critically important for the pathogenesis of EAE [20,

21], as GM-CSF promotes the migration of immune

cells into the CNS [22]. Thus, the increased presence of

CCR6

Tcells in the CNS correlates with the enhanced

polarization of T cells into GM-CSF-producing cells.

Thus, the reduction in the severity of clinical symp-

toms of EAE in mice with microglial IL-6 inactivation

correlated with a decrease in the percentage and ab-

solute number of inflammatory Ly6C

MHCII

mono-

cytes in the CNS, as well as with reduced IFNγ pro-

duction by T cells and an increase in the proportion

GOGOLEVA et al.908

BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

Fig. 2. IL-6 produced by microglia stimulates development of pathogenic monocytes and IFNγ production by T cells in the CNS

at the peak of EAE. a)Frequency of Ly6C

MHCII

cells among CD45

CD11b

cells in the CNS at the peak of EAE; b)absolute num-

ber of Ly6C

MHCII

cells in the CNS at the peak of EAE; c)frequency of IFNγ-producing cells restimulated with PMA/ionomycin

among CD4

TCRβ

cells in the CNS at the peak of EAE; d)frequency of FoxP3

reg

among CD4

TCRβ

cells in the CNS at the peak of

EAE. Pooled(a,c, andd) or representative(b) data are shown with number of mice for each genotype n=5-6. Data are shown as

mean ±SEM. Student’s t-test or Mann–Whitney test; *p<0.05; **p<0.01.

Fig. 3. IL-6 deletion in microglia results in the increased T cell migration and induction of GM-CSF by CD4

T cells in the CNS.

a)Frequency of CCR6

cells among CD4

TCRβ

cells in the CNS at the peak of EAE. b)Frequency of GM-CSF-producing cells re-

stimulated with PMA/ionomycin among CD4

TCRβ

-cells in the CNS at the peak of EAE. Pooled (a) or representative (b) data are

shown with number of mice for each genotype n=5-6. Data are shown as mean±SEM. Student’s t-test or Mann–Whitney test;

*p<0.05; ***p<0.001; ns,non-significant.

of protective T

reg

cells. At the same time, partial re-

sistance to EAE in mice with IL-6 inactivation in mi-

croglia may be associated with increased of T cell mi-

gration into the CNS, coupled with an increase in the

percentage of the GM-CSF-producing CD4

T cells.

IL-6 from dendritic cells not only determines

the T

17/T

reg

ratio, but also affects IFNγ and GM-

CSF production in the peripheral lymphoid organs

during EAE. It is known that one of the functions

of IL-6 in EAE is to inhibit of the transcription factor

FoxP3, which, in turn, suppresses development of pro-

tective T

reg

 [23]. On the other hand, IL-6 is crucial for

the development of T

17 cells [6]. Indeed, a decrease

in the percentage of RORγt

17 cells and an increase

in the percentage of FoxP3

reg

(Fig.  4a) were observed

in the lymph nodes at the peak of EAE in mice with

IL-6 deletion in dendritic cells. This is consistent with

previous studies on the pathogenic role of IL-6 pro-

duced by dendritic cells.

Next, we addressed cytokine production by T cells

isolated from lymph nodes and spleens of Il6

fl/fl

and

Il6

ΔDC

mice at the peak of EAE and restimulated with

PMA/ionomycin. It was found that IL-6 deletion in den-

dritic cells does not affect the production of IL-17A by

T cells (Fig.  4b), which is consistent with the literature

[6]. However, the Il6

ΔDC

mice were characterized by a

reduction in GM-CSF (Fig. 4c) and IFNγ (Fig. 4d) pro-

duction both in lymph nodes and in spleen.

Thus, mice with IL-6 deletion in dendritic cells

are characterized by an increase in the proportion of

reg

and a decrease in IFNγ and GM-CSF production by

Tcells in peripheral lymphoid organs, resulting in the

development of mild EAE symptoms. Moreover, the

results of this study indicate that IL-6 from dendrit-

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BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

Fig. 4. IL-6 from dendritic cells stimulates production of cytokines by CD4

T cells in the peripheral lymphoid organs at the peak

of EAE. a)Representative dot plots (left) and percentage (right) of RORγt

and FoxP3

CD4

T cells isolated from lymph nodes

of Il6

fl/fl

and Il6

ΔDC

mice at the peak of EAE. b-d)Frequencies of IL-17A-, GM-CSF-, and IFNγ-producing CD4

T cells isolated from

the spleen and lymph nodes and restimulated with PMA/ionomycin. Data are shown as mean ±SEM. Student’s t-test or Mann–

Whitney test; *p<0.05; **p<0.01; ns,non-significant.

ic cells may not only be involved in the induction of

pathogenic T

17 cells [6], but also stimulate GM-CSF

and IFNγ production by T cells.

CONCLUSIONS

Cytokines play a key role in the pathogenesis

of EAE. IL-6 is one of the few cytokines that is abso-

lutely required for the development of EAE [24, 25].

Although astrocytes being the main source of IL-6 in

the CNS[10], it has been shown that myeloid cells are

the main source of IL-6 in the EAE model [6]. Inter-

estingly, deletion of IL-6 in LysM

myeloid cells (mac-

rophages and neutrophils) does not affect the course

of disease [6,  26]. Microglia and dendritic cells are

critically important IL-6 producing populations in the

pathogenesis of EAE [6].

Indeed, the results of this study demonstrate that

IL-6 deletion in microglia leads to the development of

mild EAE symptoms as compared to wild type mice.

It is worth noting that in another study, IL-6 deletion

in microglia resulted in a reduction in the severity of

clinical symptoms of EAE in female but not in male

mice [16], which correlates with the predominance of

MS within the female population. In this study, mice

with IL-6 deletion in microglia showed a reduction in

the number of pro-inflammatory Ly6C

MHCII

-mono-

cytes, which play a central role in the demyelination.

This finding is consistent with the literature demon-

strating a decrease in spinal cord demyelination upon

IL-6 deletion in microglia [16]. On the other hand, this

could also indicate one of the degenerative functions

of IL-6 since the same phenotype is observed upon

IL-6 deletion in various sources in the CNS, namely as-

trocytes and neurons [16]. Furthermore, IL-6 deletion

in microglia resulted in a decrease in IFNγ production

by T cells, which, on one hand, explains the reduced

number of Ly6C

MHCII

monocytes [17], and, on the

other hand, is consistent with an increase in the per-

centage of protective T

reg

in the CNS[18].

In contrast to the decrease in clinical symptoms

of EAE, mice with IL-6 deletion in microglia exhibited

increased migration of CD4

T  cells into the CNS and

GOGOLEVA et al.910

BIOCHEMISTRY (Moscow) Vol. 89 No. 5 2024

increased production of GM-CSF. Indeed, another

study demonstrated that the infiltration of T  cells does

not change upon IL-6 deletion from various cellular

sources in the CNS [16]. Furthermore, the results ob-

tained provide evidence for the correlation between

the co-expression of CCR6 and GM-CSF in T  cells infil-

trating the CNS [27]. Taken together, these data sug-

gest that in the context of neuroinflammation, mi-

croglia may perform both protective and pathogenic

functions.

On the contrary, the results of this study highlight

the exclusively pathogenic role of IL-6 from dendritic

cells [6]. Specifically, IL-6 from dendritic cells is cru-

cial for maintaining the balance between RORγt

cells and FoxP3

reg

. A therapeutic approach target-

ing this signaling pathway by inhibiting STAT3 with a

small molecule has been recently proposed [28] for

immunomodulation of the clinical symptoms in MS pa-

tients. Interestingly, this study also demonstrated that

IL-6 from dendritic cells is essential for stimulating

production of IFNγ and GM-CSF by T cells, although

IL-6 has not traditionally been considered a cytokine

required for stimulation of GM-CSF production [21].

Thus, while IL-6 produced by microglia may have

both pathogenic and protective functions, IL-6 from

dendritic cells appears to play an exclusively patho-

genic role.

Acknowledgments. The authors are grateful to

K.  S.-N.  Atrekhany, D. M.  Potashnikova, A.  P.  Dygay, and

R.  V.  Zvartsev for helpful discussions and technical as-

sistance. The authors are thankful to S.  A.  Nedospasov

for valuable comments and general supervision of the

project. Experiments with cell sorting were support-

ed by the Development Program of the Moscow State

University (complex FACSAria SORP; Beckton Dickin-

son,USA).

Contributions. M.S.D. conceptualized and super-

vised the study; V.S.G. and Q.C.N. performed experi-

ments, discussed results of the experiments, wrote the

original draft of the paper; M.S.D. edited the manuscript.

Funding. This work was supported by the Russian

Science Foundation (grant no.23-24-00389).

Ethics declarations. All experiments with lab-

oratory animals were conducted in accordance with

the local legislation and institutional requirements.

Theauthors of this work declare that they have nocon-

flicts of interest.

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