There are no such groups. With GAP one can check this as follows:
Construct the group $G := {\rm AGL}(4,3)$:
gap> G := SemidirectProduct(GL(4,3),GF(3)^4);
<matrix group of size 1965150720 with 3 generators>
Move to the natural permutation representation of $G$ on $3^4 = 81$ points:
gap> phi := IsomorphismPermGroup(G);;
gap> H := Image(phi);
<permutation group of size 1965150720 with 3 generators>
gap> DegreeAction(H);
81
Find all conjugacy classes of $H$ of elements whose order is divisible by 9:
gap> ccl9 := Filtered(ConjugacyClasses(H),
> cl->Order(Representative(cl)) mod 9 = 0);;
gap> List(ccl9,Size);
[ 4043520, 36391680, 12130560, 24261120, 36391680 ]
gap> reps := List(ccl9,Representative);;
gap> List(reps,Order);
[ 9, 18, 9, 9, 18 ]
Compute normalizers of conjugacy class representatives in $H$:
gap> normalizers := List(reps,g->Normalizer(H,Group(g)));
[ <permutation group with 7 generators>, <permutation group with 6 generators>,
<permutation group with 7 generators>, <permutation group with 4 generators>,
<permutation group with 6 generators> ]
gap> List(normalizers,Size); # the normalizers are nicely small
[ 2916, 324, 972, 486, 324 ]
Search for transitive metacyclic subgroups of $H$:
gap> List([1..5],i->Filtered(AsList(normalizers[i]),
> g -> Order(g) mod 9 = 0 and
> IsTransitive(Group(g,reps[i]),[1..81])));
[ [ ], [ ], [ ], [ ], [ ] ]
-- There are none!
However if we allow for two orbits instead of one, there are solutions:
gap> List([1..5],i->ForAny(AsList(normalizers[i]),
> g -> Order(g) mod 9 = 0 and
> Length(Orbits(Group(g,reps[i]),[1..81])) <= 2));
[ true, true, false, false, false ]