let M be non empty TopSpace; :: thesis:
assume A1: ( M is without_boundary & M is locally_euclidean ) ; :: thesis:
for p being Point of M ex B being Basis of p st B is countable

proof

let p be Point of M; :: thesis:
consider U being a_neighborhood of p, n being Nat such that
A2: M | U, Tball ((0. (TOP-REAL n)),1) are_homeomorphic by A1, MFOLD_0:6;
set TR = TOP-REAL n;
p in Int U by CONNSP_2:def 1;
then K1: ex W being Subset of M st
( W is open & W c= U & p in W ) by TOPS_1:22;
( not Ball ((0. (TOP-REAL n)),1) is empty & Ball ((0. (TOP-REAL n)),1) is ball ) ;
then Tball ((0. (TOP-REAL n)),1),(TOP-REAL n) | ([#] (TOP-REAL n)) are_homeomorphic by Th10, METRIZTS:def 1;
then M | U,(TOP-REAL n) | ([#] (TOP-REAL n)) are_homeomorphic by A2, K1, BORSUK_3:3;
then M | U, TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #) are_homeomorphic by TSEP_1:93;
then consider f being Function of (M | U),TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #) such that
A3: f is being_homeomorphism by T_0TOPSP:def 1;
A4: ( dom f = [#] (M | U) & rng f = [#] TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #) & f is one-to-one & f is continuous & f " is continuous ) by A3, TOPS_2:def 5;
then A5: dom f = U by PRE_TOPC:def 5;
A6: f is onto by A4, FUNCT_2:def 3;
A7: Int U c= U by TOPS_1:16;
A8: p in Int U by CONNSP_2:def 1;
A9: p in dom f by CONNSP_2:def 1, A7, A5;
f . p in rng f by A8, A7, A5, FUNCT_1:3;
then reconsider q = f . p as Point of (TOP-REAL n) ;
reconsider n1 = n as Element of NAT by ORDINAL1:def 12;
consider B1 being Basis of q such that
A10: B1 is countable by FRECHET:def 2;
reconsider A = bool the carrier of (TOP-REAL n) as non empty set ;
deffunc H₁( set ) -> Element of bool the carrier of M = ((f ") .: c₁) /\ (Int U);
set B = { H₁(X) where X is Element of A : X in B1 } ;
A11: card B1 c= omega by A10, CARD_3:def 14;
card { H₁(X) where X is Element of A : X in B1 } c= card B1 from TREES_2:sch 2();
then A12: card { H₁(X) where X is Element of A : X in B1 } c= omega by A11;
for x being object st x in { H₁(X) where X is Element of A : X in B1 } holds
x in bool the carrier of M

proof

let x be object ; :: thesis:
assume x in { H₁(X) where X is Element of A : X in B1 } ; :: thesis:
then consider X1 being Element of A such that
A13: ( x = H₁(X1) & X1 in B1 ) ;
thus x in bool the carrier of M by A13; :: thesis:

end;

then reconsider B = { H₁(X) where X is Element of A : X in B1 } as Subset-Family of M by TARSKI:def 3;
A14: for P being Subset of M st P in B holds
P is open

proof

let P be Subset of M; :: thesis:
assume P in B ; :: thesis:
then consider X1 being Element of A such that
A15: ( P = H₁(X1) & X1 in B1 ) ;
reconsider X1 = X1 as Subset of TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #) ;
reconsider X2 = X1 as Subset of (TOP-REAL n) ;
X2 in the topology of (TOP-REAL n) by PRE_TOPC:def 2, A15, YELLOW_8:12;
then A16: X1 is open by PRE_TOPC:def 2;
reconsider U1 = M | U as non empty TopStruct by A8, A7;
reconsider g = f " as Function of TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #),U1 ;
A17: g is being_homeomorphism by A3, TOPS_2:56;
A18: g .: X1 is open by A16, A17, TOPGRP_1:25;
g .: X1 in the topology of (M | U) by A18, PRE_TOPC:def 2;
then consider Q being Subset of M such that
A19: ( Q in the topology of M & g .: X1 = Q /\ ([#] (M | U)) ) by PRE_TOPC:def 4;
[#] (M | U) = U by PRE_TOPC:def 5;
then A20: P = Q /\ (U /\ (Int U)) by A19, A15, XBOOLE_1:16
.= Q /\ (Int U) by TOPS_1:16, XBOOLE_1:28 ;
Q is open by A19, PRE_TOPC:def 2;
hence P is open by A20; :: thesis:

end;

for Y being set st Y in B holds
p in Y

proof

let Y be set ; :: thesis:
assume Y in B ; :: thesis:
then consider X1 being Element of A such that
A21: ( Y = H₁(X1) & X1 in B1 ) ;
reconsider g = f as Function ;
[p,(g . p)] in g by A8, A7, A5, FUNCT_1:def 2;
then [q,p] in g ~ by RELAT_1:def 7;
then [q,p] in g " by A4, FUNCT_1:def 5;
then A22: [q,p] in f " by A6, A4, TOPS_2:def 4;
q in X1 by A21, YELLOW_8:12;
then p in (f ") .: X1 by A22, RELAT_1:def 13;
hence p in Y by A21, A8, XBOOLE_0:def 4; :: thesis:

end;

then A23: p in Intersect B by SETFAM_1:43;
for S being Subset of M st S is open & p in S holds
ex V being Subset of M st
( V in B & V c= S )

proof

let S be Subset of M; :: thesis:
assume A24: ( S is open & p in S ) ; :: thesis:
set S1 = S /\ ([#] (M | U));
S in the topology of M by A24, PRE_TOPC:def 2;
then A25: S /\ ([#] (M | U)) in the topology of (M | U) by PRE_TOPC:def 4;
reconsider U1 = M | U as non empty TopStruct by A8, A7;
reconsider S1 = S /\ ([#] (M | U)) as Subset of U1 ;
S1 is open by A25, PRE_TOPC:def 2;
then A26: f .: S1 is open by A3, TOPGRP_1:25;
reconsider S2 = f .: S1 as Subset of (TOP-REAL n) ;
K: f .: S1 in the topology of TopStruct(# the carrier of (TOP-REAL n), the topology of (TOP-REAL n) #) by A26, PRE_TOPC:def 2;
reconsider g1 = f as Function ;
A28: [p,q] in f by A8, A7, A5, FUNCT_1:def 2;
p in S1 by A9, A24, XBOOLE_0:def 4;
then A29: q in S2 by A28, RELAT_1:def 13;
consider W being Subset of (TOP-REAL n) such that
A30: ( W in B1 & W c= S2 ) by A29, K, PRE_TOPC:def 2, YELLOW_8:13;
reconsider W = W as Element of A ;
set V = ((f ") .: W) /\ (Int U);
reconsider V = ((f ") .: W) /\ (Int U) as Subset of M ;
take V ; :: thesis:
thus V in B by A30; :: thesis:
A31: g1 " = f " by A6, A4, TOPS_2:def 4;
A32: (f ") .: (f .: S1) = S1 by A31, A4, FUNCT_1:107;
A33: ((f ") .: W) /\ (Int U) c= (f ") .: W by XBOOLE_1:17;
A34: S1 c= S by XBOOLE_1:17;
(f ") .: W c= (f ") .: (f .: S1) by A30, RELAT_1:123;
hence V c= S by A33, A32, A34; :: thesis:

end;

then reconsider B = B as Basis of p by A14, A23, TOPS_2:def 1, YELLOW_8:def 1;
take B ; :: thesis:
thus B is countable by A12, CARD_3:def 14; :: thesis:

end;

hence M is first-countable by FRECHET:def 2; :: thesis: